JP2013057481A - Air conditioner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To efficiently supply a mist discharging part with water to be a source of mist.SOLUTION: According to an air conditioner of the embodiment, an electrostatic atomization device allows mist discharging pins for the inside and outside of a mist discharging part attached to a pin case opposed to a front surface side of a cooling plate to suck water produced by a water generation part provided with the cooling plate, and applies high voltage to the mist discharging part to generate mist. A mist supply route part connects between the mist discharging part and the inside of an indoor unit and between the mist discharging part and an air blowout port of the indoor unit, and supplies mist to the inside of the indoor unit and the air blowout port of the indoor unit. In the mist discharging part, base ends of respective mist discharging pins are respectively exposed to a back surface of the pin case. The back surface of the pin case is inclined with respect to the water generation part so that an interval between a center part where base ends of respective mist discharging pins are attached and the water generation part is smaller than an interval between both ends where front ends of respective mist discharging pins are attached and the water generation part.

Description

  Embodiments described herein relate generally to an air conditioner.

Conventionally, this type of air conditioner has been considered to have an air cleaning function that exhibits, for example, a deodorizing action and a sterilizing action from a hygienic viewpoint. In recent years, as disclosed in Patent Document 1, for example, a configuration has been considered in which an air cleaning function is realized by mist generated by an electrostatic atomizer.
By the way, in this kind of electrostatic atomizer, in order to improve the air cleaning function, how to efficiently supply water that is a source of mist becomes a problem.

JP 2010-65972 A

  Then, the air conditioner which can supply the water used as the source of mist efficiently is provided.

  The air conditioner of this embodiment includes an electrostatic atomizer and a mist supply path unit. The electrostatic atomizer includes a water generating unit that condenses moisture in the air on the cooling plate to generate water, a pin case disposed opposite to the front side of the cooling plate included in the water generating unit, It has a mist discharge pin that is attached to the pin case and absorbs the water generated by the water generation unit, and a mist discharge portion that consists of an external mist discharge pin. Is generated. The mist supply path section connects between the mist discharge section and the interior of the indoor unit and between the mist discharge section and the air outlet of the indoor unit, and the mist generated by the electrostatic atomizer is connected to the interior of the indoor unit. Supply to the air outlet of the indoor unit. And the mist discharge | release part is attached so that the base end part of the internal mist discharge | release pin and the base end part of the external mist discharge | release pin may be exposed to the back surface of a pin case, respectively. The back surface of the pin case has a distance between the base end portion of the internal mist discharge pin and the central portion to which the base end portion of the external mist discharge pin is attached and the water generating portion, and the distal end portion of the internal mist discharge pin and The outer mist discharge pin is formed so as to be inclined with respect to the water generating portion so as to be smaller than the distance between both ends to which the tip portion of the mist discharge pin is attached and the water generating portion.

1 is a longitudinal side view showing an internal structure of an indoor unit of an air conditioner according to an embodiment. The perspective view which decomposes | disassembles and shows an electrostatic atomizer The perspective view which shows the back surface side of an electrostatic atomizer Plan view of electrostatic atomizer Front view of electrostatic atomizer Bottom view of electrostatic atomizer Vertical side view of electrostatic atomizer The partial enlarged view which expands and shows the part which a water production | generation part and a mist discharge | release pin adjoin among electrostatic atomizers.

Hereinafter, an air conditioner according to an embodiment will be described with reference to the drawings. As shown in FIG. 1, the air conditioner includes an indoor unit 10 installed indoors, and an outdoor unit (not shown) installed outside and connected to the indoor unit 10 via a refrigerant pipe. ing.
The indoor unit 10 includes a heat exchanger 13 and a cross flow fan 14 in an indoor unit housing 11. In addition, an air inlet 15 for sucking indoor air into the indoor unit housing 11 is provided in the upper part of the indoor unit housing 11, and in the lower part of the indoor unit housing 11, An air outlet 16 for blowing out the air sucked into the room is provided. The indoor unit 10 sucks indoor air from the air suction port 15 by the blowing action of the cross flow fan 14, exchanges heat with the heat exchanger 13, and blows it out from the air outlet 16. This air outlet 16 is provided with a vertical louver 17 and a horizontal louver 18. An open / close panel 19 is provided on the front side of the lower portion of the indoor unit housing 11.

  A plurality of vertical louvers 17 are arranged along the left-right direction of the indoor unit 10, and are provided so as to be rotatable in the left-right direction. The vertical louver 17 functions as a wind direction plate that changes the direction of the air blown from the air outlet 16 to the left or right, that is, a left and right wind direction plate. The horizontal louver 18 is a plate-like member extending in the left-right direction of the indoor unit 10 and is provided so as to be rotatable in the up-down direction. The horizontal louver 18 functions as a wind direction plate that changes the direction of the air blown from the air outlet 16 up and down, that is, as a vertical wind direction plate. The open / close panel 19 is a plate-like member extending in the left-right direction of the indoor unit 10, and is provided so as to be rotatable in the up-down direction. The open / close panel 19 has a function of opening and closing the front portion of the air outlet 16.

The indoor unit 10 also includes a control device (not shown) that controls the overall operation of the indoor unit 10, and based on control by the control device, air conditioning operations such as cooling, heating, and dehumidification, and indoor air Various operations such as an air cleaning operation for performing sterilization and deodorization, and a cleaning operation for cleaning the inside of the indoor unit 10 can be performed.
The indoor unit 10 includes an electrostatic atomizer 21. In the present embodiment, the electrostatic atomizer 21 is installed in the vicinity of the front portion of the heat exchanger 13 inside the indoor unit housing 11. Next, the structure of this electrostatic atomizer 21 and its peripheral part will be described with reference to FIGS. In addition, this electrostatic atomizer 21 is attached so that the back surface side faces the front surface of the heat exchanger 13.

As shown in FIG. 2, the electrostatic atomizer 21 includes a water generation unit 22, a mist discharge unit 23, an electrode 24, and the like.
The water generating unit 22 includes a Peltier element 25, a cooling plate 26, a heat radiating plate 27, and the like. The Peltier element 25 has a main body portion 25a attached to the back side of the base portion 28 of the electrostatic atomizer 21 made of, for example, a plastic material, and a connector 25b connected to a wiring connection portion (not shown) of the indoor unit 10. In this case, the cooling plate 26 is formed in a rectangular plate shape, and is attached to the front side of the base portion 28 of the electrostatic atomizer 21, that is, the side opposite to the side on which the main body portion 25a of the Peltier element 25 is attached. It is done. The surface of the cooling plate 26 is substantially flush with the surface of the base portion 28, and an insulating sheet 29 made of, for example, PET resin (PET: polyethylene terephthalate) is attached to the surface of the cooling plate 26 and the surface of the base portion 28. Attached. Thereby, electrical insulation is ensured. The heat radiating plate 27 is made of, for example, a metal material, is attached to the back side of the base portion 28 to which the main body portion 25a of the Peltier element 25 is attached, and is fixed by a fixture 30 as shown in FIG.

  In the water generating unit 22 configured as described above, the cooling plate 26 is cooled by the cooling action by the Peltier element 25. And the water | moisture content in air condenses on the surface of the cooling plate 26 cooled in this way, and, thereby, the electrostatic atomizer 21 produces | generates the water used as a mist, ie, the water used as a mist source. . In this case, since the insulating sheet 29 is attached to the surface of the cooling plate 26, water is actually generated on the surface of the insulating sheet 29.

  In this case, the mist discharge portion 23 is composed of an internal mist discharge pin 23a and an external mist discharge pin 23b, and is made of, for example, a plastic material disposed facing the front side of the cooling plate 26 provided in the water generating portion 22. Each pin case 31 is attached. These internal mist release pin 23a and external mist release pin 23b are formed of a felt material made of a porous material having water absorption and water retention, for example, fibrous polyester, etc. It has a cylindrical shape, but its tip is rounded and pointed.

  The pin case 31 has a hole 31a for pin support at substantially the center thereof, and also has a support portion 31b for pin support, located on both ends of the hole 31a. ing. The internal mist discharge pin 23a and the external mist discharge pin 23b are supported by the pin case 31 by inserting the proximal end side into the hole 31a and sandwiching the distal end side between the support portions 31b. ing. As shown in FIGS. 4 and 8, the base end portion of the internal mist discharge pin 23a and the base end portion of the external mist discharge pin 23b supported by the pin case 31 are the back surface 31e of the pin case 31, respectively. It protrudes to the water production | generation part 22 side from and is exposed to the back surface 31e of the pin case 31. As shown in FIG. In addition, an internal discharge hole 31 c that opens into the indoor unit housing 11 is formed in a portion of the pin case 31 on the tip end portion side where the internal mist discharge pin 23 a is attached.

  Of the insulating sheet 29, the cooling plate 26 is a portion of the base end portion of the internal mist discharge pin 23a supported by the pin case 31 and the base end portion of the external mist discharge pin 23b that is exposed to the back surface 31e of the pin case 31. Proximity to the part facing the. Therefore, the water generated by the water generating unit 22 is a portion exposed from the back surface 31e of the pin case 31 mainly in the base end portions of the internal mist discharge pin 23a and the external mist discharge pin 23b, as will be described in detail later. The water is absorbed from the inside and penetrates into the whole of the internal mist discharge pin 23a and the external mist discharge pin 23b so as to be retained.

  The electrode 24 is supported by an electrode support portion 31 d provided in the pin case 31. The electrode 24 is supported by the electrode support portion 31d of the pin case 31, and the base end portion thereof is connected to a high voltage power source (not shown). Further, the electrode 24 has two contact portions 24a at the tip thereof. Each of the contact portions 24a is formed in a U-shaped cross section, and comes into contact with the internal mist discharge pin 23a and the external mist discharge pin 23b held by the pin case 31 as described above from the front side. The contact portions 24a also have a function of holding the internal mist discharge pin 23a and the external mist discharge pin 23b from the front side.

  A pin cover 32 made of, for example, a plastic material is attached to the front side of the pin case 31 that supports the internal mist discharge pin 23a, the external mist discharge pin 23b, and the electrode 24 as described above. An external discharge hole 32a that communicates with the duct 33 shown in FIG. 1 is formed in a portion of the pin cover 32 on the side where the external mist discharge pin 23b is attached. The duct 33 is made of, for example, a plastic material and extends to the air outlet 16 of the indoor unit 10. Further, as shown in FIGS. 4 to 6, an internal discharge hole 32b is formed in a portion of the pin cover 32 on the tip end portion side where the internal mist discharge pin 23a is attached. Accordingly, in the electrostatic atomizer 21, the internal mist discharge pin 23a communicates with the interior of the indoor unit housing 11 via the internal discharge hole 31c and the internal discharge hole 32b, and the external mist discharge pin 23b is externally connected. The air outlet 16 communicates with the air discharge hole 32 a and the duct 33.

  In addition, air inlets 32c and 32d are provided in front of the pin cover 32 at positions opposed to the internal mist discharge pin 23a and the external mist discharge pin 23b. Part of the air flowing in the outdoor unit housing 11 by the action flows into the electrostatic atomizer 21 through the air inlets 32c and 32d, and the internal mist discharge pin 23a and the external mist discharge pin 23b. To come into contact. The air flowing toward the internal mist discharge pin 23a is supplied to the interior of the indoor unit housing 11 through the internal discharge hole 31c, while the air flowing toward the external mist discharge pin 23b is discharged outside. The air is supplied to the air outlet 16 through the hole 32 a and the duct 33. In this case, the portion forming the path from the internal mist discharge pin 23a to the internal discharge hole 31c and the internal discharge hole 32b corresponds to the internal mist supply path portion 100 shown in FIGS. A portion that forms a path from the mist discharge pin 23b to the air outlet 16 via the external discharge hole 32a and the duct 33 corresponds to the external mist supply path 200 shown in FIGS.

  As shown in FIG. 7, an inclined portion 32 e that is inclined downward toward the back side of the electrostatic atomizer 21 is provided in a portion of the pin cover 32 that is located below the water generating portion 22. In addition, when water is excessively generated in the water generating unit 22, the water flows out from the inclined portion 32e without difficulty. In this case, the inclination of the inclined portion 32e is set to about 10 degrees with respect to the horizontal direction. The pin cover 32 is provided with an electrode cover portion 32f that covers the electrode 24 described above.

  Further, as shown in FIG. 8, the back surface 31e of the pin case 31 where the base end portion of the internal mist discharge pin 23a and the base end portion of the external mist discharge pin 23b constituting the mist discharge portion 23 are exposed In this case, the distance D1 between the center portion of the back surface 31e of the pin case 31 to which the base end portion of the mist discharge pin 23a for use and the base end portion of the mist discharge pin 23b for external use are attached is about 1 mm. On the other hand, the distance D2 between the both ends of the back surface 31e of the pin case 31 to which the tip of the internal mist discharge pin 23a and the tip of the external mist discharge pin 23b are attached and the water generating part 22 are set. However, in this case, the distance between the back surface 31e of the pin case 31 and the water generating unit 22 is set to be about 3 mm, and gradually decreases toward the center. To have.

  That is, the back surface 31e of the pin case 31 has a gap D1 between the water generating portion 22 and the central portion where the base end portion of the internal mist discharge pin 23a and the base end portion of the external mist discharge pin 23b are located. With respect to the water generation unit 22, the distance between the front end portion of the internal mist discharge pin 23 a and the front end portion of the external mist discharge pin 23 b and the water generation unit 22 is smaller than the gap D 2. It has an inclined shape. That is, the shape of the back surface 31e of the pin case 31 has a V-shaped gap formed symmetrically about the central portion in plan view. Note that the interval D1 and the interval D2 can be set to appropriate values as long as the relationship of D1 <D2 is satisfied.

  Here, the water droplets generated by the water generation unit 22 described above gradually increase and generally have a diameter of about 4 mm. Accordingly, when the water droplets generated by the water generating unit 22 reach the back surface 31e side of the pin case 31, the surface tension side acts on the central portion side of the back surface 31e of the pin case 31 that is closer to the water generating unit 22 due to the action of the surface tension. Be drawn to. And the water attracted to the center part side of the back surface 31e of the pin case 31 is the base end part of the internal mist discharge | release pin 23a exposed to the water production | generation part 22 side from the center part vicinity of the back side 31e of the pin case 31, and external use The mist discharge pin 23b comes into contact with the base end portion and is absorbed by the internal mist discharge pin 23a and the external mist discharge pin 23b.

  Further, as shown in FIG. 5, the two internal mist discharge pins 23a and the external mist discharge pin 23b constituting the mist discharge portion 23 are both upward from the horizontal direction h indicated by a one-dot chain line in FIG. Are inclined with a predetermined angle θ. Therefore, even if water is excessively absorbed by the internal mist discharge pin 23a and the external mist discharge pin 23b, the water is absorbed by the tip of the internal mist discharge pin 23a and the external mist discharge pin 23b. It does not permeate excessively on the tip side. As a result, it is possible to prevent water from dripping from the front end portion of the internal mist discharge pin 23a and the front end portion of the external mist discharge pin 23b, and in particular, water flows out from the external discharge hole 32a. Can be avoided.

  Further, when water is excessively absorbed by the internal mist discharge pin 23a and the external mist discharge pin 23b, the water is supplied to the base end side of the internal mist discharge pin 23a and the external mist discharge pin. It tends to be distributed more on the base end side of the pin 23b. As a result, excessively absorbed water is concentrated from the base end side of the internal mist discharge pin 23a and the base end side of the external mist discharge pin 23b, that is, from the center of the mist discharge portion 23. It can be dripped at the inclined portion 32e of the pin cover 32, and the excessively generated water is efficiently discharged. The predetermined angle θ can be set to an appropriate value.

  The electrostatic atomizer 21 configured as described above applies a high voltage (for example, −6 kV) to the electrode 24 from a high voltage power source (not shown), and thereby the internal mist discharge pin 23a is passed through the electrode 24. A high voltage is applied to the external mist discharge pin 23b. As described above, the internal mist discharge pin 23a and the external mist discharge pin 23b include water generated by the water generation unit 22. Therefore, when electric charges concentrate on the tip portions of the internal mist discharge pin 23a and the external mist discharge pin 23b, energy exceeding the surface tension is given to the water contained in the tip portion. As a result, the water at the tip portions of the internal mist discharge pin 23a and the external mist discharge pin 23b is split, that is, Rayleigh split, and water is discharged from the tip portions of the internal mist discharge pin 23a and the external mist discharge pin 23b. Is atomized and released in the form of a mist. That is, an electrostatic atomization phenomenon occurs.

  Here, the water particles released in a mist form are charged and contain hydroxy radicals generated by the energy. Accordingly, the hydroxy radical having a strong oxidizing action is released together with the mist from the internal mist release pin 23a and the external mist release pin 23b, and the bacteria can be sterilized and deodorized by the action of the hydroxy radical. Thus, the mist containing the hydroxy radicals released from the internal mist release pin 23a and the external mist release pin 23b is supplied to the inside of the indoor unit 10 through the internal mist supply path section 100, and is also externally used. It is supplied to the outside of the indoor unit 10 through the mist supply path unit 200.

  The electrostatic atomizer 21 does not include the other electrode corresponding to the charged internal mist discharge pin 23a and external mist discharge pin 23b, that is, a counter electrode. In this case, in the indoor unit 10 in which the electrostatic atomizer 21 is installed, a member that is grounded via a ground wire or the like, for example, a metal housing of the indoor unit 10 is charged with an internal mist discharge pin. 23a and the other electrode corresponding to the external mist discharge pin 23b.

  That is, the electrostatic atomizer 21 uses the counter electrode corresponding to the internal mist discharge pin 23a and the external mist discharge pin 23b charged by a high voltage from a high voltage power supply, and converts the internal mist discharge pin 23a and the external mist discharge pin 23a The structure is not provided in the vicinity of the mist discharge pin 23b. Therefore, the discharge itself from the internal mist discharge pin 23a and the external mist discharge pin 23b becomes very gentle, and no corona discharge occurs. Therefore, for example, ozone or the ozone oxidizes nitrogen in the air. The generation of harmful gases such as nitrogen oxides, nitrous acid, and nitric acid generated by this is suppressed.

In the indoor unit 10 having the above-described configuration, a control device (not shown) drives the electrostatic atomizer 21 to apply a high voltage to the electrode 24, and generates hydroxy radicals from the internal mist release pin 23a and the external mist release pin 23b. Generate mist containing. Accordingly, the electrostatic atomizer 21 supplies the generated mist to the inside of the indoor unit 10 through the internal mist supply path unit 100 and also through the external mist supply path unit 200, the air outlet of the indoor unit 10 16 is supplied. Thereby, generation | occurrence | production of a microbe and generation | occurrence | production of an odor can be suppressed inside and outside the indoor unit 10.
Moreover, the structure by the electrostatic atomizer 21 and the mist supply path parts 100 and 200 is simple. Therefore, the indoor unit 10 can be configured without causing a complicated structure, and the mist generated by the electrostatic atomizer 21 can be efficiently contributed to the air cleaning function.

  The air conditioner of one embodiment described above includes an electrostatic atomizer and a mist supply path unit. The electrostatic atomizer includes a water generating unit that condenses moisture in the air on the cooling plate to generate water, a pin case disposed opposite to the front side of the cooling plate included in the water generating unit, It has a mist discharge pin that is attached to the pin case and absorbs the water generated by the water generation unit, and a mist discharge portion that consists of an external mist discharge pin. Is generated. The mist supply path section connects between the mist discharge section and the interior of the indoor unit and between the mist discharge section and the air outlet of the indoor unit, and the mist generated by the electrostatic atomizer is connected to the interior of the indoor unit. Supply to the air outlet of the indoor unit. And the mist discharge | release part is attached so that the base end part of the internal mist discharge | release pin and the base end part of the external mist discharge | release pin may be exposed to the back surface of a pin case, respectively. The back surface of the pin case has a distance between the base end portion of the internal mist discharge pin and the central portion to which the base end portion of the external mist discharge pin is attached and the water generating portion, and the distal end portion of the internal mist discharge pin and The outer mist discharge pin is formed so as to be inclined with respect to the water generating portion so as to be smaller than the distance between both ends to which the tip portion of the mist discharge pin is attached and the water generating portion.

  According to this configuration, the water generated by the water generation unit is concentrated on the center of the back surface of the pin case using surface tension, and the base end of the internal mist discharge pin exposed at the center and the external mist discharge It can be transported to the base end portion of the pin, and water as a mist source can be efficiently supplied to the mist discharge portion.

  The above-described embodiment has been presented as an example, and is not intended to limit the scope of the invention. The novel embodiment can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. This embodiment and its modifications are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

  In the drawings, 10 is an indoor unit, 11 is an indoor unit housing, 16 is an air outlet, 21 is an electrostatic atomizer, 22 is a water generation unit, 23 is a mist discharge unit, 23a is an internal mist discharge pin, 23b Is an external mist discharge pin, 26 is a cooling plate, 31 is a pin case, and 100 and 200 are mist supply paths.

Claims (2)

A water generator that generates water by condensing moisture in the air on the cooling plate, a pin case that is disposed opposite to the front side of the cooling plate provided in the water generator, and is attached to the pin case, An electrostatic mist generating unit that has a mist discharging part composed of an internal mist discharging pin and an external mist discharging pin that absorbs water generated by the water generating part, and generates a mist by applying a high voltage to the mist discharging part. An atomizer,
Connecting between the mist discharge unit and the interior of the indoor unit and between the mist discharge unit and the air outlet of the indoor unit, the mist generated by the electrostatic atomizer is disposed inside the indoor unit and the interior unit. A mist supply path section for supplying to the air outlet of the indoor unit;
With
The mist discharge portion is attached so that the base end portion of the internal mist discharge pin and the base end portion of the external mist discharge pin are exposed on the back surface of the pin case, respectively.
The back surface of the pin case has a space between the base portion of the internal mist discharge pin and a central portion to which the base end portion of the external mist discharge pin is attached and the water generating portion. The tip of the pin and the tip of the external mist discharge pin are formed to be inclined with respect to the water generator so as to be smaller than the distance between the both ends to which the tip is attached and the water generator. Air conditioner characterized by.   2. The air conditioner according to claim 1, wherein the internal mist discharge pin and the external mist discharge pin are inclined upward.

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