KR100996565B1 - Air conditioner - Google Patents

Abstract

It is an object of the present invention to provide an air conditioner having an electrostatic misting device which does not need to replenish water for electrostatic misting, and which efficiently increases the amount of electrostatic misting water generated. A cooling fan for generating water and a blower fan for blowing air into the room, an outside air suction mechanism, and an electrostatic misting device, the cooling device for generating water for cooling the suction outside air sucked by the outside air suction mechanism; And an air conditioner having a frequency path for guiding condensation water obtained in the water generation cooling device to a mist-fogging part for electrostatic fog, wherein the heat absorbing surface of the water generation cooling device is formed by a cylindrical cooling means, and A part of the outer surface of the cooling means is a heat exchange surface of the low temperature portion of the cooling device for generating water, and the inner surface of the cooling means. It is achieved by a heat exchange surface with the outside air intake.

Outside air suction device, blower fan, electrostatic misting device, heat exchange surface, condensation water

Description

Air conditioner {AIR CONDITIONER}

The present invention relates to an air conditioner, and more particularly, to an air conditioner equipped with an electrostatic misting device.

An air conditioner circulates indoor air with a heat exchanger, adjusts it by a heating, cooling, dehumidification function, etc., and blows it into the room, and air-conditions the room. At this time, in addition to the adjustment of temperature and humidity, various functions are added to clean the room and to make a comfortable space.

Indoors are associated with life, and various sources of odor are generated, some of which are detected as odors by stimulating the odor cells of the nose. These sources of odor are gas, droplets, very small dust, etc. If left unattended, they will collide with ions in the air ionized by spacecraft or the like to charge, settle due to gravity, or collide with walls by air currents, It is adsorbed by fixtures such as furniture, floors, ceilings, and the like, and is removed from the air in the room, or it is decomposed and denatured in the presence of active substances, and the smell disappears. However, the source of the odor that is not decomposed and adsorbed and settled to a barrier or the floor is raised by being floated in the indoor air when the temperature rises, hits the wind, or is blown off by cleaning.

As described above, in order to decompose and modify an odor generating source attached to a wall or the like by adsorption or the like, attempts have been made to impart an active substance such as OH radicals to fine water droplets, prolong its life, encounter the odor generating source, and deodorize it.

As one of them, a method of deodorizing the room by releasing the water of the fine particles that have been electrified by the electrostatic fog method to the air that is blown into the room has been devised, and various studies have been conducted to embody it.

In general, it is known that when water of fine grains, which have been electrified by electrostatic fog, is suspended in a room, radicals are generated by the electric charges, thereby exhibiting a deodorizing action.

Patent document 1 and patent document 2 are mentioned as this kind of prior art. That is, Patent Literature 1 discloses an air conditioner in which an electrostatic mist eliminator is freely provided at a blower port downstream of a heat exchanger and a fan. The electrostatic misting device includes a water flow section for collecting water for electrostatic misting, an application electrode for applying a voltage to the water, and an opposite electrode.

Patent Document 2 further includes a housing portion for holding a water applying electrode, an opposite electrode, and a water conveying member therein, and a steam generating portion for supplying water to the water conveying member by supplying steam into the housing portion. Is disclosed. The steam generator is to evaporate by heating the water collected in the pot to the heater. It is disclosed that the supply of water to the pot is performed by a water supply tank installed detachably. The electrostatic misting device and the humidification apparatus provided with this are demonstrated with the maintenance of a humidification by the said electrostatic misting device, and having no maintenance and causing trouble even in continuous operation for a long term.

Patent Document 3 discloses condensation water by cooling air on a flat endothermic surface of the Peltier element in order to eliminate the trouble of water replenishment of the user, and the condensation water slides on the flat endothermic surface to form a center or outer peripheral image on the endothermic surface. Disclosed is an electrostatic misting device configured to be sent to a water conveying unit which is mounted upright. In order to generate condensation water more efficiently and send it to the water conveying unit, water condensation water is conveyed by performing a hydrophobic treatment on the surface of the heat absorbing surface or by forming a groove for water induction on the surface of the heat absorbing surface in a radial shape. It is described that it is preferable to provide a frequency shape for guiding to negative.

[Patent Document 1] Japanese Unexamined Patent Publication No. 2005-282873

[Patent Document 2] Japanese Patent Application Laid-Open No. 2004-358362

[Patent Document 3] Japanese Unexamined Patent Publication No. 2007-209982

Since the patent document 1 needs to be removed from the jet port of the air conditioner installed on the wall at the time of supplying water to the electrostatic misting device, it is necessary to devise to properly prepare the scaffolding and to identify the supply time. In addition, it is necessary to disassemble the electrostatic mist removing device further to remove the applied electrode and the like, and then replenish the water, thus requiring some knowledge and effort of dissemination. In Patent Document 2, maintenance is unnecessary, but water supply to the steam generator must be performed in a water supply tank.

In addition, Patent Literature 3 says that the user does not have to trouble the water supply, but the condensation generated is configured to slide on the flat heat absorbing surface and to be sent to the water conveying unit installed on the center or outer periphery of the heat absorbing surface. It is necessary to level the endothermic surface in order to send condensed water to the water conveying unit without waste. In addition, it is easy to be condensed in that it is necessary to send air to the heat absorbing surface by the fan to condense moisture in the air on the heat absorbing surface, and to slide the water absorbing surface on the heat absorbing surface as it is and to send it to the water conveying unit. Or evaporate so that it does not escape with the air. That is, in order to efficiently send the water condensed on the heat absorbing surface to the water conveying section, as described in the Examples, the surface of the heat absorbing surface is hydrophobicly treated or the groove for water induction is formed on the surface of the heat absorbing surface. It is preferable to provide a frequency shape for guiding the condensation water into the water conveying unit, such as forming the water.

However, as described above, a hydrophobic shape for guiding condensation water into the water conveying part such as hydrophobic treatment of the surface of the heat absorbing surface or forming a groove for water induction in the radial shape on the surface of the heat absorbing surface can be efficiently Even if it conveys, the water film which condensed between the surface of the heat absorption surface and air by surface tension will exist even if it becomes thin. The temperature of the water film existing between the surface of this heat absorbing surface and air is necessarily higher than the temperature of the surface of the heat absorbing surface. Since the air contacts the surface of the water film having a temperature higher than the temperature of the surface of the heat absorbing surface, the temperature difference becomes small, and the condensation amount of moisture in the air is reduced. In addition, the thermal conductivity of the endothermic surface is usually made of a material higher than the thermal conductivity of water. Therefore, the dew condensation rate does not increase so much that the air contacts the surface of the water film having low thermal conductivity, and the condensation amount does not increase so much. Therefore, in a situation where the humidity or temperature of the indoor air where the electrostatic fog device is installed is difficult to condense, it is conceivable that the water for electrostatic fog is insufficient.

The present invention is not only devised to adequately grasp the time of supplying water for electrostatic fog, and it is not necessary to supply water, and also has an electrostatic fog device for efficiently increasing the amount of water for electrostatic fog. To provide an air conditioner.

The technical problem to be achieved in the present invention is an air conditioner having a cross flow fan that ventilates the air at the same time to ventilate the heat exchanger,

Induce the outside air suction mechanism, the electrostatic misting device, the water generation cooling device for cooling the suction outside air sucked by the outside air suction mechanism, and the condensation water obtained by the water generation cooling device to the electrostatic fog device. Is achieved by having a frequency path.

The air conditioner of Claim 2 takes in the heat of the high temperature part of the said water generating cooling apparatus, and heats it to outside air.

The air conditioner of Claim 3 gives super water-repellent treatment to the heat absorption surface of the said water generation cooling apparatus.

In the air conditioner of Claim 4, the heat absorbing surface of the said water generating cooling apparatus is located downstream of the suction outside air rather than the heat radiating surface of the said water generating cooling apparatus.

The air conditioner of Claim 5 flows the sorted air outside the suction outside air which flows through the heat radiating surface of the said water production cooling apparatus to the heat absorption surface of the said water production cooling apparatus.

The air conditioner of Claim 6 uses the Peltier element as said cooling device for water production.

The air conditioner of Claim 7 has a control apparatus which controls the temperature of the heat absorbing surface of the said Peltier element below the dew point temperature of the classifying outside air which flows through a cylindrical inner surface.

An air conditioner according to claim 8 has a jet external air damper for controlling the ventilation to the heat absorbing surface of the cooling device for producing water, and closes the jet external air damper when the outside air temperature is below a predetermined temperature.

The air conditioner of Claim 9 installs a temperature sensor in a downstream heat exchange part, and stops the said water generation cooling apparatus when the temperature which the said temperature sensor shows is below a 1st predetermined value during operation of the said water generation cooling apparatus. It is.

The air conditioner of Claim 10 prohibits the stop for thawing of the said water generating cooling apparatus for a 1st predetermined time from the last stop for thawing.

The air conditioner of Claim 11 is equipped with the blowing fan for ventilating air to a heat exchanger at the same time, and to blow air into a room, an outside air suction mechanism, and an electrostatic fog device, and this static fog device is sucked in by the outside air suction device. In the air conditioner which has the water generation cooling apparatus which cools | sucks the outside air, and the frequency path which guides the dew condensation water obtained by the said water generation cooling apparatus to the misting part which electrostatically mists, The heat absorption of the said water generation cooling apparatus. The surface is formed by a cylindrical cooling means, and a part of the outer surface of the cooling means is used as a heat exchange surface with the low temperature portion of the water generating cooling device, and the inner surface of the cooling means is a heat exchange surface with the suction outside air. .

The air conditioner of Claim 12 forms a fin in the inner surface of a cooling means.

The air conditioner of Claim 13 gives super water-repellent treatment to the inner surface of a cooling means.

The air conditioner of Claim 14 provides a heat exchange surface with room air in the other part of the outer surface of a cooling means.

The air conditioner of Claim 15 installs the said fin in the two opposing surfaces of the internal air path of a cooling means, The straight line which connects the pin tip of one side, and the pin tip of the surface on the opposite side to the straight line which connects the base of a pin It is in the middle of the straight line to connect.

The air conditioner of Claim 16 makes the average height of the fin provided in the surface close to the low temperature part heat exchange surface among the two opposing surfaces higher than the average height of the fin provided in the surface on the opposite side.

The air conditioner according to claim 17 has an outlet air path in which the external air flows upward in the downstream direction of the air outside the endothermic surface of the cooling means, and a water conveyance maintenance means is provided below the bottom of the air outlet air path. Water can move from a conveyance repair means to the said water path.

The air conditioner according to claim 18 is provided with a jet air flow path in which the jet air flows downwards upstream of the jet air outside the endothermic surface of the cooling means.

According to the present invention, it is possible to efficiently obtain the water for electrostatic misting from the outdoor air, and it is not necessary to devise a design for properly grasping the time for supplying the water for electrostatic misting, and it is not necessary to supply water, and also for the electrostatic misting. It is possible to provide an air conditioner having an electrostatic misting device for efficiently increasing the amount of water produced.

EMBODIMENT OF THE INVENTION Hereinafter, the Example of the air conditioner concerning this invention is described using drawing.

[First Embodiment]

A first embodiment of the present invention will be described with reference to the drawings. The same reference numerals in the drawings indicate the same or equivalent.

First, the whole structure of an air conditioner is demonstrated using FIG. 1, FIG. 1 is a configuration diagram of an air conditioner of an embodiment. Fig. 2 is a side sectional view of the indoor unit of the air conditioner.

The air conditioner 1 connects the indoor unit 2 and the outdoor unit 6 to the connection pipe 8 to air condition the room. The indoor unit 2 has an indoor heat exchanger 33 at the center of the housing base 21 and a horizontal flow fan 311 which is a blowing fan having a length substantially equal to the width of the heat exchanger 33 downstream of the heat exchanger 33 ( The cross flow fan is arrange | positioned, the condensation base 35, etc. are provided, these are covered with the makeup frame 23, and the front panel 25 is provided in the front surface of the makeup frame 23. As shown in FIG. An air inlet port 27 for sucking indoor air and an air blower port 29 for ejecting air whose temperature and humidity are adjusted are disposed above and below the makeup frame 23. The blowing airflow from the crossflow fan 311 flows into the blowing air path 290 which has a width substantially the same as the length of the crossflow fan 311, and the left-right direction of the airflow plate 295 arrange | positioned in the middle of the blowing air path 290, and the left-right direction of airflow And the up-and-down wind direction plate 291 mix | blended with the blower outlet 29 is made to deflect | deviate the up-down direction of airflow, and to be able to jet to indoors.

A cross flow fan 311 is provided downstream of the air flow of the indoor heat exchanger 33. When the cross flow fan 311 rotates, indoor air is blown out from the air suction port 27 provided in the indoor unit 2 through the indoor heat exchanger 33 and the cross flow fan 311 to the air blower outlet 29.

The housing base 21 has a basic interior such as a cross flow fan 311, a filter 231 and 231 ′, an indoor heat exchanger 33, a condensation support 35, a vertical wind direction plate 291, and a left and right wind direction plate 295. The structure is installed. And these basic internal structures are contained in the housing 20 which consists of the housing base 21, the makeup frame 23, and the front panel 25, and comprise the indoor unit 2. As shown in FIG.

In addition, a lower portion of the front panel 25 is provided with a display portion for displaying driving conditions and a light receiving portion for receiving an infrared operation signal from a separate remote control 5.

The air blower outlet 29 formed in the lower surface of the makeup frame 23 is arrange | positioned adjacent to the division part with the front panel 25, and is communicated with the blower air flow path 290 inside. The two upper and lower wind direction plates 291 are configured to substantially conceal the blowing air path 290 in the closed state and have a large curved surface continuous to the bottom of the indoor unit 2. These up-and-down wind direction plates 291 are rotated at a desired angle by the drive motor according to the instruction from the remote control 5 with the rotary shafts provided at both ends as a support point, and the air blower outlet 29 To keep it open. When the operation of the air conditioner 1 is stopped, these up-and-down wind direction plates 291 are controlled to close the air blower outlet 29.

The left and right wind direction plates 295 are rotated by the drive motor with the rotational shaft provided at the lower end as a support point, rotated according to the instruction from the remote control 5, and maintained in that state. As a result, the blowing air is blown out in the desired directions on the left and right sides. Further, by instructing from the remote control 5, the upper and lower wind direction plate 291 and the left and right wind direction plate 295 may be periodically shaken during operation of the air conditioner 1, and the air may be blown out periodically to send a wide range of indoor air. .

The movable panel 251 is configured to be rotated by a drive motor with the rotational shaft provided at the lower portion as a supporting point to open the front air intake 230 'during operation of the air conditioner 1. As a result, indoor air is sucked into the indoor unit 2 from the front side air intake 230 'during operation. When the air conditioner 1 is stopped, it is controlled to close the front air intake 230 '.

The indoor unit 2 is provided with a control board in the electrical equipment box inside, and a microcomputer is installed in this control board. This microcomputer receives signals from various sensors such as an indoor temperature sensor and an indoor humidity sensor and receives an operation signal from the remote control 5 through the light receiving unit. On the basis of these signals, the microcomputer controls the cross flow fan 311, the movable panel drive motor, the vertical wind direction drive motor, the left and right wind direction drive motors, and the like, and is in charge of communication with the outdoor unit 6, and the indoor unit 2 ) To control overall.

The filters 231 and 231 'are for removing dust contained in sucked indoor air and are arranged to cover the suction side of the indoor heat exchanger 33. The dew condensation support 35 is disposed below the lower ends of the front and rear sides of the indoor heat exchanger 33 so as to receive condensed water generated in the indoor heat exchanger 33 during the cooling operation or the dehumidification operation. The condensed water collected is discharged to the outside through the drain pipe 37.

Next, the electrostatic fogging device of the embodiment will be described with reference to Figs. 3 is a schematic diagram showing the configuration of an electrostatic fogizer of an indoor unit. Fig. 4 is an explanatory diagram showing the air path of the airflow flowing through the water generating unit of the electrostatic fogizer. Fig. 5 is a perspective view of the indoor unit taken off from the make-up frame and viewed from the left.

The electrostatic misting device 42 is provided near the outside air suction mechanism 32, which will be described later, on the side of the blowing air passage 290 as shown in Figs. 3 and 5, and the high voltage generating device 450 and the high voltage generating device 450 A conductor 429 extending from the high voltage terminal 451 of the c), and a fog electrode 422 and an ion electrode 428 electrically contacting the conductor 429 when absorbed by the fog connection 424. And a water generator 440 for the water supplied to the mist electrode 422.

The high voltage of -3kV to -6kV generated by the high voltage generator 450 is applied to the misting electrode 422 and the ion electrode 428 to supply water to the misting electrode 422 from the water generating unit 440. As a result, the water of the finely-charged fine grains is discharged from the tip of the mist electrode 422, and ions are released from the ion electrode 428.

In the embodiment, the discharge air passages 430 of the above-mentioned charge-fogging fine grains are installed by protruding from the air blower side wall 290c of the indoor unit 2 of the air conditioner 1 to the air blower 290. It was.

In addition, the water generating unit 440 is configured to condense moisture from the air by using the Peltier effect. The cooling unit 425 for condensing moisture in the air to the low temperature unit 442 of the Peltier element 441 is used as the high temperature unit. At 444, a heat sink 338 cooled by the outside air and the surrounding indoor air is provided. The cooling means 425 is a heat absorption surface formed of a cylindrical cooling block.

Details of the water generating unit 440 will be described later.

It is said that the water of the charged fog fine particles floating in the room evaporates to the surrounding air and finally disappears, but the above action takes place until it disappears. desirable.

The crossflow fan 311 is driven, and the electrostatic misting device 42 is driven to apply a negative high voltage from the high voltage generating device 450 to the misting electrode 422 and the ion electrode 428.

At this time, corona discharge is generated from the ion electrode 428 toward the surrounding atmosphere, whereby electrons are released to generate ions. The ions are discharged to the blowing air passage 290 to be blown into the room by the blowing airflow, thereby improving the quality of the indoor air.

In conjunction with the operation of the electrostatic fog device 42 described above, energization of the water generating unit 440 to the Peltier element 441 is performed to cool the low temperature portion 442 of the Peltier element 441 to sandwich the insulating sheet 443. Cooling means 425 formed of a cylindrical cooling block cools cold, and when the temperature is lower than the dew point temperature of the air flowing in the cooling means 425 and the surroundings, the moisture in the air flowing inside and the surroundings is reduced. It condenses on this cooling means 425.

The condensed water is delivered through the water passage (water conveyance repairing means 423 and the water passage 422b) which connects the cooling means 425 to the mist forming section 422a. This water conveyance repair means 423 is comprised from the water absorbing water conveyance member 423a, and the water supply repair material 423b.

Specifically, the dew condensation is received by the absorbent water conveying member 423a at the lower portion of the cooling means 425 and the water supply repair material 423b, and the misting portion 422a is passed through the water supply portion 422b of the misting electrode 422. Until the capillary phenomenon. When the water reaches the misting section 422a, the electrostatic misting starts by the high voltage applied to the misting section 424, and the water of the finely misted fine grains discharged to the jetting passage 290 is discharged into the jetting air stream. Erupted indoors. At this time, the cross-flow fan 311 can generate a uniform flow with less disturbance to send the blowing air far away in the room, so that the water of the charge-fogging fine grains discharged from the electrostatic misting device also quickly rides through this uniform flow. It reaches far to the room and effectively exerts the deodorizing action of the fine mist of charged mist. In addition, the blower fan of the air conditioner may send blowing air to a distant position in the room by a combination of a fan having a large amount of air and a direction of the wind direction control means to improve directivity in addition to the cross flow fan (311). This is appropriately employed in relation to the size and cost of the air conditioner. As a fan used in these, a large number of air conditioners use a sirocco fan, a thin one for a thin turbo fan, and a relatively thin one for a transverse flow fan.

Next, the outside air suction mechanism will be described with reference to Figs. Fig. 6 is a sectional view of the indoor unit as seen from the left side of the outdoor air suction mechanism of the indoor unit. Fig. 7 is a perspective view of the outside air suction mechanism from the rear portion.

The outside air suction mechanism 32 is disposed at one side in the indoor unit 2. Specifically, the outside air suction mechanism 32 is incorporated in the side opposite to the blowing motor 313 for the cross flow fan 311.

The outside air suction mechanism 32 has a suction port 325 of the outside air suction mechanism, which draws fresh outdoor air into the room, at its rear portion. The outside air passage 39 is connected to the inlet 325 of the outside air suction mechanism, and the outside air passage 39 is connected to the indoor unit 2 and the outdoor unit 6 together with a connection pipe 8 to connect the pipe holes of the house. It passes through the outside, and is led to the outside, the tip end of the outside air passage 39 is opened to the outside air, and the connection pipe 8 is connected to the outdoor unit 6.

The outside air suction mechanism 32 has a state of intake operation and operation stop. In addition, in the intake operation, outdoor air is sucked from the inlet 325 of the outside air intake mechanism and blown into the room. In addition, it is not necessary to provide the outdoor air blower outlet which blows into a room directly, and the blower outlet may be provided in the place of the circulation path of circulation airflow, and, even if it does not have a clear air blower path, as a result, it is indoors. Ejecting can achieve the purpose of intake. In addition, in the state of driving stop, natural wind does not flow.

The operation of the external air suction mechanism 32 may be operated in combination with the air conditioning operation of the indoor unit 2, or may be operated by the external air suction mechanism 32 alone. It is also possible to provide a timer to the outside air intake mechanism 32 to automatically stop the operation after a predetermined time of operation.

That is, in the intake operation, outdoor air collects dust having a particle diameter of 10 μm or more with high efficiency close to 99.9% by the outdoor air filter 325b placed in the middle of the suction door outdoor air intake air passage 328, and blows it into the room as clean air. As such an outside air filter 325b, what added the deodorizing function to the charging filter, for example is known. In this way, the fine dust and odor contained in the air are removed by the air filter 325b and sucked into the air suction fan 321. In addition, when the operation is stopped, the outside air suction fan 321 stops, and the intake operation stops.

As shown in Figs. 6 and 16, the housing portion 284b of the air filter 325b is formed by cleaning the filters 231 and 231 'with a cleaning brush provided on the brush supporting frames 262 and 262'. It is provided in the back of the removal dust storage part 284a which accommodates dust.

The housing portion 284b of the outside air filter 325b is provided at the rear of the storage portion 284a of the removal dust, and the outside air intake air passage 328 extends from the rear to the front, and is bent to the upper outside air intake fan 321. It is to be inserted into the part which is halfway in the middle. The wall of the air passage of the bent portion of the outside air intake air passage 328 is composed of the heat sink 338 of the Peltier element 441 described above to absorb the heat of the high temperature portion 444 of the Peltier element 441 to radiate heat to the outside air. have.

The air filter 325b is permanently charged to a filter made of resin. The air filter 325b removes dust in suctioned air and cleans it, and supplies it to the room.

328c is an outside air passage connecting portion for connecting the outside air passage 39 to the inlet 325 of the outside air suction mechanism, and connects the outside air passage 39 to the outside of the outside air by a hose band or the like.

In addition, as shown in FIGS. 3, 5, and 17, the discharge unit 430 of the outside air suction mechanism 32 and the electrostatic mist eliminating device 42 has an axial direction of the cross flow fan 311 of the indoor unit 2. Are arranged on the same side and are provided close to the Peltier element 441. For this reason, the heat sink 338 and the frequency part 422b can be arrange | positioned compactly, the temperature difference in the heat sink 338 can be made small, and the heat sink 338 can be made small. In addition, the water supply volume in the water receptacle 422b can be reduced, and the time for water to reach the condensation 422a at the time of the initial start of operation in which the water receptacle 422b is dried can be shortened. Do.

In addition, as shown in FIG. 16, the heat sink 338 is provided in the bent part of the outside air suction air path 328 of the outside air suction mechanism 32. As shown in FIG. This dissipates heat in the bent portion where the disturbance of the intake airflow is large, and the heat dissipation is improved. In the embodiment, the heat dissipation fins 338a and 338b are provided on the heat dissipation plate 338 to promote heat dissipation, and condensation occurs reliably in the low temperature portion.

A jet outside air inlet 329a is provided adjacent to the outside air intake mechanism jet port 326 to suck in the outside air for water generation to the water generation unit of the electrostatic fogizer 42. The jet external air inlet 329a is provided with the jet external air damper 329b which is opened and closed by the damper drive motor 329c.

When the filters 231 and 231 'are scratched with a cleaning brush, the dust attached to the filters 231 and 231' is scraped off by the cleaning brush to be removed and moved to the vibration damping brush 270 or 270 'at the end, and the dust removal hopper inside is removed. 281 is dropped and stored in the removal dust storage part 284a provided in the dust collecting box 284. The stored dust is kept clean by flipping the front panel 25 appropriately, as shown by the dotted line in FIG. 6, by grasping the handle 284c, pulling it out and cleaning it. At this time, by cleaning and replacing the outside air filter 325b, both cleaning can be performed at once, and maintenance becomes easy.

Next, the water generating unit of the electrostatic misting device will be described with reference to FIGS. 4 and 8 to 16. 8 is a cross-sectional view of the indoor unit seen from the right direction of the outside air intake mechanism. Fig. 9 is a perspective view of the outside air suction mechanism and the electrostatic misting device as seen from the front. 10 is a perspective view of cooling means of the electrostatic fogizer. 11 is an enlarged view of the cooling means. Fig. 12A is a perspective view of the cooling means portion of the water generating portion of the electrostatic fogizer. Fig. 13 is a sectional view taken along the line C-C in Fig. 14A. Fig. 14A is a side sectional view of the cooling means portion. Fig. 15 is a sectional perspective view showing the inside of the water generating unit. 16 is an exploded perspective view of the Peltier element heat dissipation unit of the water generation unit.

In Fig. 4, reference numeral 338 denotes an outdoor air path heat sink, 425 a cooling means formed in a heat absorbing surface in a tubular shape, 441 a Peltier element, 442 a low temperature portion, 443 an insulating sheet, and 444 a high temperature portion. 10 and 11, 425e is a pin, 425f is a pin b, 425d is a receiving portion of a water conveying member, 425g is a central air passage, and 425h is an installation hole.

As shown in Fig. 8, the classified outdoor air inlet 329a is divided into an outdoor air passage 329, a cooling means internal air passage 425c, and a classification outlet air passage 331 as shown in Fig. 8 while the classified outdoor air damper 329b is opened. It is in communication with the exhaust port 333. In the case of performing the electrostatic fog operation, the damper drive motor 329c is driven together with the outside air suction fan 321 and the Peltier element 441, and a part of the suction outside air is flowed into the classified outside air path 329 with the classified outside air. The cooling means 425 condenses the moisture of the classified outdoor air. The fractionated outdoor air deprived of moisture flows through the fractional outlet air path 331 and is exhausted from the fractional exhaust port 333 through the exhaust air path 38 to the outside.

The cooling means 425 of the embodiment is made of a cooling block in which an endothermic surface (cooling surface) is formed in a rectangular cylindrical shape as shown in FIG. The cooling means 425 closes the outer surface of the cooling wall a 425a by inserting the electrical insulation sheet 443 in close contact with the low temperature portion 442 of the Peltier element 441, and flows through the internal air passage 425c. Cools the outside air classified in) and condenses the moisture in the outside air.

In the embodiment, a fin a 425e is provided on the cooling wall a 425a side and a fin b 425f on the cooling wall b 425b side in the tubular direction on the cylindrical inner surface of the cooling means 425. The front end of the pin a 425e and the front end of the pin b 425f are separated from each other, and a central air passage 425g is formed therebetween. The height of the pin a 425e, which is close to the low temperature portion 442 of the Peltier element 441, is high, and the height of the pin b 425f far from the low temperature portion 442 of the Peltier element 441 is lower than that. In addition, super water-repellent treatment is performed on the inner surface of the cooling means 425 (cooling wall a 425a / cooling wall b 425b), which is a tubular endothermic surface including the surfaces of the fin a 425e and the fin b 425f. Was carried out.

When water condenses on the inner surface of the cooling means 425 (cooling wall a (425a), cooling wall b (425b)) that is an endothermic surface treated with super water-repellent treatment, the water droplets or super water-repellent water drops as if the water droplets of the condensate water were extremely small. It is bounced by the process and scattered in the air.

In addition, super water-repellent and water-repellent differ greatly in the contact angle of a water droplet and a contact surface. That is, when the contact surface of the water droplet is 0 degrees, the inclination angle (contact angle) of the end surface of the water droplet with respect to the contact surface is 90 ° or more for water repellency, high water repellency for 110 ° to 150 °, and super water repellency for 150 ° or more. do. The water repellency is largely grown in the form of water droplets attached to the surface condensed in a hemispherical shape with surface tension. On the other hand, the water droplets of super water-repellent condensate into a substantially spherical shape, and the water droplets fly into the air as if they were thrown out of the condensed surface in a state of extremely small size. This tiny droplet of water is scattered into the air, apparently floating in a mist. However, when this is magnified with a high-speed shutter while irradiating light, a state in which it is strongly scattered in the air as if it is thrown out from the condensed endothermic surface (cooling means 425) is taken.

The larger the contact angle of the water repellent is, the more spherical the water droplets become, and the water droplets do not become friendly to the contact surface (heat absorbing surface) and are easily separated from the contact surface, and are rapidly scattered in the air.

Water in the outside air cooled by the cooling means 425 (cooling wall a 425a and cooling wall b 425b) is cooled on the surface of the cooling means 425 (cooling wall a 425a and cooling wall b 425b). Condensation. However, the condensed water is super water-repellent because the cooling means 425 (cooling wall a 425a, cooling wall b 425b) is super water-repellent. It is bounced off the endothermic surface and scattered into the air. The very small water droplets bounced off the heat absorbing surface of the cooling means 425 and scattered into the air are attached to the drop or heat absorbing surface by contacting, coalescing with very small water droplets, and grow large by rolling down the heat absorbing surface. 423a) and flows in the direction of the outlet air passage 331 located on the downstream side of the cooling means 425 (cooling wall a 425a, cooling wall b 425b) together with the air flow. It is attached in contact with the wall. The water droplets attached to the wall surface of the outlet air passage 331 flow down the wall surface of the air passage and are absorbed by the water conveyance repairing means 423 at the lower side, and are supplied to the electrostatic fogizer through the water passage.

The flow rate of the airflow at this time is good enough that the water droplets bounce off the endothermic surface of the cooling means 425 and are not discharged from the fractionating exhaust port 333 through the outlet air passage 331 together with the airflow. . The flow velocity in the cylindrical cooling means of an Example is 0.2 m / sec.

The flow rate depends on various conditions, for example, the size of the wall spacing dimension of the cylindrical cooling means 425 or the region sold (weather conditions). As in the embodiment, when the wall surface spacing dimension of the cooling means 425 is small, the flow velocity can be made faster than the case where the cooling means 425 is large. That is, if the droplets condensed on the wall surface and splashed by the super water-repellent water easily reach the opposing wall surface, the amount of floating in the air stream and flowing downstream decreases.

In addition, when the wall surface of the outlet air passage 331 is water-repellent or water-repellent, the wall surface quickly drops and is absorbed by the water conveyance repairing means 423. Therefore, the wall surface of the outlet air passage 331 is more suitable for supplying water for electrostatic mist than the hydrophilic wall surface.

When the outside air temperature decreases, the cooling means 425 (cooling wall a (425a) and cooling wall b 425b) becomes 0 degrees or less, and the floating very small droplets are cooled by the cooling means 425 (cooling wall a (425a)). It is frosted and attached to the wall of the fractionation outlet air path 331 located downstream of the wall b (425b). At this time, if the temperature of the sorted outside air passing through the cooling means 425 (cooling wall a 425a / cooling wall b 425b) is 0 degrees or more, the frost attached to the wall of the fractional outlet air passage 331 melts and the fractional outlet The wall of the air path 331 is dropped and absorbed by the water conveyance repairing means 423 to become fog water. In this way, the cooling means 425 (cooling wall a (425a) and cooling wall b (425b)) does not freeze, so that the temperature and humidity conditions of the outside air where water for fog can be obtained are expanded to the low temperature and low humidity side. Can be.

Moreover, the outer surface of the cooling wall b 425b of the cooling means 425 condenses the moisture of indoor air which enters the indoor unit 2 by making a part thereof face the air inside the indoor unit 2. At this time, the moisture of the indoor air condensed by the outer surface of the cooling wall b (425b) is additionally induced by the driving of the indoor unit 2, the electrostatic misting device 42, the outside air suction fan 321, and the Peltier element 441. If the flow of ambient air in cooling wall b 425b is too strong, the temperature of cooling wall b 425b will not drop to the dew point temperature of ambient air, and condensation from ambient air will not occur. There is a case. In particular, there is such a concern if a lot of indoor air heated during heating operation flows in.

For this reason, in the embodiment, the wall 343 of the surrounding air path as shown in Figs. 4 and 9 is provided to limit the amount of ambient indoor air flowing in the ambient air path 341. At this time, the flowing air flowing through the surroundings is obstructed by the wall 343 of the surrounding air path, and only a part thereof flows into the surrounding air path 341 as a thick line arrow, and condenses moisture retained by the cooling wall b 425b. Could.

As a result of the experiment, when the distance between the cooling wall b 425b and the wall 343 of the surrounding air passage is 3 mm or less, the convection inside is suppressed, and the ambient indoor air flowing in the surrounding air passage 341 is stabilized from the top to the bottom. It was clear that an appropriate amount of ambient indoor air flowed into the surrounding air path 341 when flowing smoothly and the upper opening had a width of 1.5 mm or more.

The water absorbing water conveying member 423a and the water supply repairing material 423b are provided on the inner surface of the cooling means 425 and the lower part of the outer surface as the water conveying repairing means 423. Receive moisture, indoor air moisture. The absorbent water conveying member 423a and the water supply repair material 423b are made of a porous or fibrous material so that water condensed by a capillary phenomenon can move, and both members are in contact with each other. Water moves to the water supply repair material (423b) through the contact surface.

In place of the water supply repair material 423b, there is a hole in which the power portion 422b corresponding to the source of the mist electrode 422 is inserted so that the power portion 422b is inserted to absorb the water absorbing member 423a, The water retained in the water supply repair material 423b is supplied to the misting unit 422a through the water receptacle 422b in a capillary phenomenon.

In addition, the heat dissipation plate 338 cooling the Peltier element 441 faces the air intake air passage 328 of the outside air suction mechanism 32 and the surrounding indoor air, and the air path heat dissipation fin 338a and the surrounding heat dissipation fin 338b on each side thereof. ) Is being installed. As a result, the heat sink 338, the air path heat sink fins 338a, and the surrounding heat sink fins 338b are sufficiently cooled by the intake air and the surrounding room air, thereby reliably cooling the cooling means 425 to the dew point temperature of the outside air and the surrounding room air. Can be controlled.

In addition, although the Peltier element 441 was used as an apparatus to cool the cooling means 425 in the Example, if there is the ability to condense moisture from the surrounding air, it is a cooling apparatus for water generation other than Peltier element, for example, a refrigerant | coolant. It may be a coffin.

Next, the airflow of the cooling means and the behavior of the condensed very small water droplets will be described with reference to Figs. 13 and 14 (a).

The sorting outside air shown by the hollow arrow flowing through the sorting outside air path 329 flows downward just before entering the cooling means 425, U-turns where the cooling means 425 is located, and is followed by the cooling means 425. The outlet air path 331 flows upward and is exhausted to the outside from the exhaust port 333 provided at a position higher than the cooling means 425.

Hereinafter, the classified outside air which passes through pin a (425e) of the low temperature part 442 side of the Peltier element 441 of the internal air path 425c of the cooling means 425 is described. A part of the sorted outside air introduced into the cooling means 425 hits the end face of the pin a 425e at the inlet of the cooling means 425 and is classified into upper and lower portions as shown by a thick solid arrow to the upper and lower fin a 425e. Enter the path between the pins that were inserted.

Heat is taken away by heat absorption surfaces, such as the surrounding fin a (425e) and a cylindrical inner surface, and the contained moisture condenses here. Since the condensed water is subjected to super water repellent treatment on the heat absorbing surface of the cooling means 425, a considerable amount is thrown off the heat absorbing surface and becomes a very small drop of water and flows downstream with the airflow. Since the airflow hits the front end face of the fin a 425e when entering the cooling means 425, the direction is rapidly changed and the airflow is disturbed. Thus, very small droplets splashed in the airflow come into contact and grow into large droplets.

Further, the water droplets condensed on the heat absorbing surface of the cooling means 425 subjected to the super water-repellent treatment are pushed into the airflow in the shape of water droplets close to the spherical shape, and rolled on the pin a 425e to flow from the end face of the fin a 425e. Roll down to the middle.

The same thing happens to the sorted outside air passing through the pin b 425f on the side away from the low temperature portion 442 of the Peltier element 441 of the internal air passage 425c of the cooling means 425, so that the moisture in the sorted outside air is absorbed by the lower portion. It is absorbed by the water conveyance member 423a.

Next, the classified outside air which passes through the central air path 425g sandwiched between the pin a 425e and the pin b 425f of the internal air path 425c of the cooling means 425 is described. Among the classified outdoor air introduced into the central air path 425g, the air flow in the center portion is further cooled by the cooling means without contacting the pins a 425e and b 425f as shown by the thin solid arrows. As shown in the figure, it exits into a curved shape.

However, the airflow flowing in the portion closest to the pins a (425e) and the pins (425f) among the sorted outside air that is intended to flow into the central air path (425g) hits the tips of the pins (425e) and (b) 425f. Is reduced so that some enter the passage between the pins and some return to the central air passage 425g. At this time, the water droplets colliding with the airflow flowing through the passage between the fins and mixed and bounced in the airflow also come into contact with each other, thereby increasing the chance of coalescence and increasing water droplets. The enlarged water droplets fall into the central air path 425g and are absorbed by the absorbent water conveying member 423a at the bottom.

In addition, the returned airflow is accelerated by the airflow in the center portion, and part of the flow is returned to the airflow flowing between the fins from the side edges of the pins a425 and 425f, and the other part is joined to the airflow in the center portion. To join. In this way, the airflow is disturbed when the airflow flowing through the center portion and the airflow flowing through the pinned part are combined within the central air passage 425g. As a result, the water droplets contained in the airflow increase the chance of contact and coalescing, and the water droplets gradually increase, and the larger water droplets fall as if falling or rolling, and are absorbed by the absorbent water conveying member 423a at the lower portion.

14, the airflow flowing through the central air path 425g intersects the pins 425e and b 425f as shown in the figure. From this, airflows flowing in the vicinity of the pins 425e and 425f generate vortices at the side ends of the pins when they cross at the side ends of these pins. By this vortex, the airflow flowing in the inner surface of the cooling means 425 is stirred, and the boundary layer of the airflow formed on the inner surface of the cooling means 425 is reduced or reduced. As a result, the moisture in the air is efficiently cooled on the inner surface of the cooling means 425, so that condensation can be performed efficiently, so that the amount of water for misting can be increased.

Since the discharged outside air discharged from the cooling means 425 becomes partial enlarged flow at the exit side end faces of the fin a 425e and the fin b 425f, the flow is disturbed, and the direction of the airflow is changed upward. The larger water droplets are reduced in velocity due to gravity and the speed difference with the smaller droplets is increased, thereby increasing the chance of coalescence by contacting the droplets with the larger droplets, thereby increasing the droplets, falling into the air stream, or the water repellency of the exit air passage 331. It adheres in contact with this weak wall, falls along the wall, flows through the bottom surface of the outlet air passage 33l, and is absorbed by the absorbent water conveying member 423a.

At this time, if there are protrusions, recesses or the like which are resistant to the flow of the air flow in the air flow passage 329 or the air outlet air passage 331, the air flow is more disturbed, and the recovery of water droplets is improved.

Next, as shown in Figs. 12A and 14A, instead of the absorbent water conveying member 423a, a cylindrical water conveying member 423c having a cylindrical shape may be used. When the cylindrical water conveying member 423c is used, the airflow is disturbed by the concave space of the cylindrical water conveying member 423c, so that the water droplets in the airflow contact and coalesce. As a result, the supply amount of the water for electrostatic fog can be increased, and very small droplets can be prevented from being discharged from the jet exhaust port 333 through the air flow.

In summary, the air conditioner of the embodiment is an air intake mechanism, an electrostatic misting device, a water generation cooling device for cooling the suction outside air sucked by the outside air suction mechanism, and a condensation obtained by the water generation cooling device. It has a frequency path leading the water to the mist of the electrostatic mist.

According to the air conditioner of this embodiment, the outside air suction fan installed in the outside air intake air path sucks the outside air as necessary, and continuously condenses the moisture of the outside air by the water generation cooling device, and the condensed water is fogged through the water passage. The room can be deodorized by supplying it continuously to the misting unit of the apparatus and by charging a sufficient amount of fine grains of water from the electrostatic misting unit and flowing it into the room.

At this time, if moisture is obtained from the ambient air in the room, the humidity in the room drops slightly, but since moisture is obtained from the inhaled air, the humidity in the room increases slightly, and the evaporation of the charged fine grains of water is suppressed until extinction. The longer the time is, the more distant objects can be reached, which can have a deodorizing effect over a wider range. In addition, since the main parts of the outside air suction mechanism and the water generating cooling apparatus are installed in the indoor portion, maintenance is easy. This can provide an air conditioner in which the range of the deodorizing effect is not narrowed and the electrostatic misting device is not required to supply water from the outside.

In addition, the air conditioner of the embodiment absorbs heat from the high temperature portion of the water generating cooling device to radiate heat to the outside air.

As a result, outdoor air having a predictable temperature range is used for cooling the high temperature portion of the water generation cooling device, so that heat dissipation of the high temperature portion of the water generation cooling device is reliably performed, so that the low temperature portion of the water generation cooling device can be sufficiently cooled. Can be designed. For this reason, the heat dissipation of the high temperature part of the water generation cooling apparatus can be performed suitably, and the dew condensation of the low temperature side advances smoothly, and the air conditioner which supplies the water to the mist part smoothly can be provided.

Moreover, the air conditioner of an Example performs super water-repellent treatment on the heat absorption surface of the said water generation cooling apparatus.

As a result, the moisture in the intake outside air cooled by the heat absorbing surface condenses on the heat absorbing surface, but since the heat absorbing surface is super water-repellent, some of the water condenses on the heat absorbing surface, but most of the water does not adhere to the heat absorbing surface, but becomes water droplets and scatters on the heat absorbing surface. . The scattered fine water droplets collide with and adhere to the more hydrophilic wall surface of the air path following the heat absorbing surface. The attached water droplets drop the walls of the air path by their own weight, are absorbed by the absorbent water conveying member 423a at the lower portion, and move through the dilution path to the electrostatic misting device.

When the outside air temperature decreases, the heat absorbing surface becomes 0 degrees or less, and the fine water droplets scattered are frosted on the wall of the fractional outlet air passage 331 leading to the heat absorbing surface. At this time, if the temperature of the sorted outside air passing through the heat absorbing surface is 0 degrees or more, frost attached to the wall of the sorted outlet air path 331 melts and falls down the wall of the sorted outlet air path 331 and is absorbed by the absorbent water conveying member 423a. It becomes fog water. Thus, even if the endothermic surface freezes, the water for misting can be obtained from the wall of the downstream flow outlet 331, so that the temperature and humidity conditions of the outside air that can supply the water for misting can be extended to the low temperature and low humidity side. have. For this reason, the air conditioner which can expand the temperature and humidity conditions of the outside air which can supply water to a misting device to the low temperature side can be provided.

In addition, the air conditioner of the embodiment is located in the heat absorbing surface of the cooling device for generating water downstream of the suction outside air than the heat dissipating surface of the cooling device for producing water.

As a result, when the outside air temperature is low, the intake air is heated up on the heat radiation surface upstream, so the temperature after cooling on the downstream heat absorption surface increases by that much, and the temperature of the wall of the air passage rises, thereby preventing freezing after trapping water droplets. . Thus, even when the outside air temperature is low, it is possible to provide an air conditioner that can supply the moisture condensed from the outside air to the electrostatic misting device.

Moreover, the air conditioner of an Example flows the sorted outside air classified from the suction outside air which flows through the heat radiating surface of the said water generation cooling apparatus to the heat absorption surface of the said water generation cooling apparatus.

As a result, the temperature of the suction outside air is increased by the heat radiation at the heat dissipation surface, but the rate at which the temperature rises is small because the amount of the suction outside air flowing is large. On the other hand, in the heat absorbing surface, the amount of classified outdoor air flowing is equal to 1 of the amount of moisture intake air flowing through the heat radiating surface, so the classified outdoor air flowing in the heat absorbing surface is sufficiently cooled, and the moisture retained becomes condensed and becomes water droplets and is captured on the wall of the air path do.

In addition, since the outside air flowing through the heat absorbing surface can be supplied to the room as an air supply, the heat from the heat radiating surface contributes to the reduction of the heating load. can do. The reverse phenomenon occurs at the time of cooling, resulting in an increase in the cooling load. However, since the heating operation time is overwhelmingly greater than the cooling operation time, the reduction effect of the heating load is greater throughout the year. As a result, even when the outside temperature is low and the dew point temperature is low, a sufficient amount of water can be supplied to the electrostatic fogizer, and an air conditioner can be provided which suppresses the increase in the heating load caused by the air supply during heating. .

Further, the air conditioner of the embodiment is provided with an external air damper for controlling the ventilation to the heat absorbing surface of the cooling device for generating water.

As a result, when operating the electrostatic mist device, the classified outdoor air damper is opened to flow the classified outdoor air to the heat absorbing surface of the water generating cooling device. When the electrostatic mist device is not operated, the classified outdoor air damper is closed to close the classified outdoor air path. . In this way, when the electrostatic mist eliminator is not operated, no outside air flows through the classified outdoor air path, and unnecessary classification does not occur. Therefore, suction and discharge of unnecessary external air are eliminated, and the suctioned outdoor air can be effectively supplied to the room, and the external air suction fan is unnecessary. Does not consume power This avoids the wasteful operation of the outside air intake fan, thereby providing an air conditioner that saves energy.

Further, the air conditioner of the embodiment includes an air cleaning filter having a deodorizing function in the air path of the outside air intake mechanism.

In general, the air cleaning filter can collect dust having a particle diameter of 10 μm or more with a high efficiency of nearly 99.9%. According to the air conditioner of the embodiment, since the minute dust and the odor contained in the intake air are removed to reach the endothermic surface, contaminants do not adhere to the endothermic surface, and no odor is dissolved in the condensed water droplets. However, since the dust that becomes the nucleus when water droplets condense on the endothermic surface passes through the air cleaning filter, there is no problem with regard to the generation of fine water droplets on the endothermic surface. This can provide an air conditioner in which the endothermic surface is kept clean and in addition, the supply water to the electrostatic fogizer is kept clean.

Moreover, the air conditioner of an Example discharges the outside air cooled by the endothermic surface of the said water generating cooling apparatus to the exterior.

As a result, when the heating is cooled, the sorted outdoor air that is cooled and reduced in moisture is discharged to the outside, thereby suppressing the heating load than when discharging to the interior. In addition, during cooling, the outdoor air discharged to the outside is cooled to reduce moisture. However, when the outside temperature is high, the water is cooled to reduce moisture, but the total heat of the air is still larger than the total heat of the indoor air. As described above, when the outside air temperature is high, the cooling load becomes a large cooling load close to the maximum cooling load that can cope with the air conditioner, so that the air conditioner cannot afford the capacity.

In such a case, it is preferable to suppress the further increase of the cooling load by discharging the outside air having a large amount of heat to the outside even though the water is reduced by cooling. For this reason, the air conditioner which suppresses the increase of a heating load and a cooling load, and also suppresses drying of the room at the time of heating can be provided.

In addition, the air conditioner of the embodiment supplies most of the suction outside air sucked by the outside air suction mechanism into the room.

As a result, the suction function of the outside air serving as the water source of the electrostatic fog device and the air supply function into the room can be realized by the same fan. This makes it possible to provide an air conditioner that keeps the indoor unit compact and can reduce parts.

Moreover, the air conditioner of an Example is provided with the frequency path | route which guide | induces the moisture condensed from the indoor air to the said electrostatic misting apparatus, since the heat absorption surface of the said water generation | cooling apparatus also faces surrounding indoor air.

This makes it possible to extract moisture from the ambient air in the room in addition to the moisture extracted from the sorted outside air, thereby increasing the amount of water that can be obtained.

This can provide a moisture-rich air conditioner that can be obtained as water for electrostatic misting.

In addition, the air conditioner of an Example forms the heat absorbing surface of the said water generating cooling apparatus into a cylindrical shape, makes the inner surface of a cylindrical shape the heat exchange surface with the external air, and a part of the cylindrical outer surface of the cooling apparatus for water production | generation As a heat exchange surface with a low temperature part, the heat exchange surface with indoor air is provided in the other part of a cylindrical outer surface.

As a result, the tubular endothermic surface is connected to the air passage for the external air flow to flow the external air discharged therein. On the other hand, a part of the cylindrical outer surface is formed on a flat surface, in close contact with the low temperature part of the water generating cooling device, and most of the other surface faces the indoor air. By doing so, the heat of the sorted outside air flows into the tubular outer surface closely contacted with the low temperature part of the water generating cooling device → the cold part of the water generating cooling device, and the heat of the sorted outside air is taken away. Condensation. On the other hand, the heat of the surrounding indoor air flows to the low temperature part of the tubular outer surface → the water generating cooling device in close contact with the low temperature part of the indoor air → the cylindrical outer surface → the water generating cooling device, and the heat of the surrounding air is deprived. Moisture is condensed.

In this way, by providing a cylindrical endothermic surface and using both inner and outer surfaces artfully, heat from both the outside air and the surrounding indoor air can be absorbed at the low temperature portion of the water generating cooling device, thereby reducing the number of components. The heat absorbing surface can be formed without increasing the whole oil area. This makes it possible to obtain electrostatic mist water from both outdoor air and indoor air, and to provide an air conditioner without waste in the construction of the indoor unit.

In addition, the air conditioner of the embodiment has a wall of the surrounding air path facing the heat absorbing surface facing the indoor air of the water generating cooling device, and is arranged around the space formed between the wall of the ambient air path and the heat absorbing surface. A gap is formed in which indoor air can flow in or out.

In general, the indoor unit of the air conditioner is provided with a fan for circulation of indoor air, and by rotating the fan for circulation, the indoor air flows to the heat exchanger through which the refrigerant flows to perform heat exchange between the refrigerant and the indoor air. have. When the fan for circulation is turned, it is sucked from the air inlet, heat exchanged in the refrigerant heat exchanger, and the gaps and spaces between the various functional parts arranged in the indoor unit, in addition to the main air flows from the air outlet port into the room, cannot be ignored. The flow is generated.

This type of flow is determined by the position of the individual parts arranged, the amount of heat generated, etc., but this is similar to the flow of the channel connected like a delta of the estuary of the river, so it is very difficult to predict the pattern of the flow in advance. Do.

Since the above-described water generating cooling device is placed in such a difficult flow, if the amount of the air that hits the endothermic surface endothermic from the room air is too large, the heat exchange amount is increased, but the temperature of the endothermic surface rises and in extreme cases endothermic The surface temperature exceeds the dew point temperature of the air striking the endothermic surface and the sensible heat ratio is 1, so that moisture does not condense. Even if it is not so extreme, the sensible heat ratio approaches 1, making it difficult to condense moisture. On the contrary, if the amount of air hitting the heat absorbing surface is too small, the temperature of the heat absorbing surface decreases, but in extreme cases where the heat exchange amount decreases and the amount of flowing air becomes zero, the temperature of the heat absorbing surface continues to decrease toward the heat absorbing surface. The water molecules are moved little by little by diffusion, resulting in a state of freezing. In either case, the amount of water that condenses decreases, so it is necessary to keep the amount of air hitting the endothermic surface within an appropriate range.

According to the air conditioner of the embodiment, the heat absorbing surface is enclosed by the wall of the surrounding air passage so as to prevent the amount of air hitting the heat absorbing surface of the water generating cooling apparatus from being excessive, and a air passage communicating with the air in the indoor unit is formed. This suppresses supply of excess indoor air to the heat absorbing surface, does not increase the temperature of the heat absorbing surface excessively, and heat-exchanges with the indoor air to condense moisture in the indoor air.

At this time, since openings are provided above and below the heat absorbing surface, air in the indoor unit cooled on the heat absorbing surface is discharged from the lower opening, and air in the new indoor unit is supplied to supplement this from the upper opening. In this way, since the air in the indoor unit is smoothly supplied to the heat absorbing surface, the distance between the heat absorbing surface and the wall of the surrounding air path can be reduced, and the device can be miniaturized.

This facilitates condensation from the indoor air supplied to the electrostatic misting device, thereby providing an air conditioner capable of miniaturizing the device.

Moreover, the air conditioner of an Example makes the average distance between the said heat absorbing surface and the wall of the surrounding air path 3 mm or less.

In general, the heat transfer between the plates when the air is inserted into the vertical parallel plates becomes convective heat transfer due to convection based on the temperature difference between the two plates when the distance between the plates is large, but increases when the distance between the plates decreases. The flow and the downflow interfere with each other and convection is not performed well. In addition, when the distance between the plates becomes smaller, the movement of air stops, resulting in a thermal movement in which the thermal conductivity of the air is mainly used. At this time, if the upper side and the lower side of the parallel flat plate are open to the surrounding space of the flat plate temperature on the high temperature side, as described above, a downward flow due to cooling by the heat absorbing surface is generated and flows out from the lower opening, so as to compensate for this. Ambient air flows in from the opening.

According to the air conditioner of the embodiment, in the surrounding air path between the heat absorbing surface and the wall of the surrounding air path, convection is suppressed, and the downward flow due to cooling on the heat absorbing surface becomes dominant, so that an appropriate amount of air in the indoor unit is supplied to the heat absorbing surface. Condensation proceeds smoothly. This can provide an air conditioner in which convection in the surrounding air path is suppressed so that an appropriate amount of indoor air is supplied to the heat absorbing surface, so that condensation from the indoor air can be performed smoothly.

Moreover, the air conditioner of an Example has the opening of an inlet port substantially square, and the average width of the short side is 1.5 mm or more.

As a result, the amount of indoor air supplied to the heat absorbing surface does not become too small, and an appropriate amount of air in the indoor unit is supplied to the heat absorbing surface, and condensation proceeds smoothly. As a result, the amount of indoor air supplied to the heat absorbing surface is not reduced, and thus an air conditioner in which condensation from the indoor air can be performed smoothly can be provided.

Next, the general operation of the Peltier element employed as the cooling device for generating water of the embodiment will be described. When a current flows through the Peltier element, it absorbs heat at the heat absorbing portion and heat radiation at the heat radiating portion. At this time, if the heat absorbing portion is placed in the low temperature heat source and the heat dissipating portion is placed in the high temperature heat source, heat can be transferred from the low temperature heat source to the high temperature heat source. The amount of heat transfer depends on the current and the voltage, and the temperature of the low temperature heat source that can be reached is also related to the difference between the temperature of the high temperature heat source, the heat radiation at the heat dissipation portion, the heat absorption portion, and the heat absorption.

In recent years, the improvement of the Peltier element has progressed and a compact and reliable product has emerged. Among them, the Peltier element which can control the temperature of a low temperature part was used in the Example.

When the Peltier element is operated, the dew point temperature of the outside air is approximately obtained based on the information from the outside air temperature sensor and the outside air humidity sensor provided in the outdoor unit 6 of the air conditioner. The Peltier element 441 is controlled by subtracting the offset value which changes according to the outside air temperature from the approximation value of this dew point temperature as the target temperature of the low temperature part of the Peltier element 441. In this way, condensation can be reliably generated on the heat absorbing surface of the water generating unit. In addition, when the outside air humidity sensor is not provided, the dew point temperature is approximated from the information of only the outside air temperature sensor, for example, assuming a relative humidity of 60%, and the offset value is slightly increased. I can do it without a trouble driving.

As described above, the air conditioner of the embodiment uses the Peltier element 441 as the cooling device for generating water.

In general, a low-power Peltier element can be compactly constructed, and further, by lowering the direct current, a low temperature portion and a high temperature portion can be obtained.

According to the air conditioner of the embodiment, the low temperature portion of the small Peltier element 441 is brought close to the indoor and outdoor air, and the Peltier element 441 is brought close to the low temperature portion by operating the Peltier element 441 so that the temperature of the low temperature portion is lower than the dew point temperature of the air. It can condense the moisture contained in the air. In addition, one end of the absorbent water conveying member 423a is provided so as to receive the condensed water, and the condensed water received by the absorbent water conveying member 423a is guided to the mist-forming section by the frequency path.

As a result, a small water generating cooling device that can be stored in an indoor unit can provide an air conditioner that supplies misting water to the electrostatic misting device without supplying water from the outside.

Thus, the air conditioner of an Example has a control apparatus which controls the temperature of the heat absorbing surface of the said Peltier element 441 to below the dew point temperature of the classifying outside air which flows through a cylindrical inner surface.

As a result, the moisture of the intake air is condensed on the heat absorbing surface to generate water droplets for electrostatic misting. This makes it possible to provide an air conditioner that can reliably condense moisture and supply it to an electrostatic misting device.

In addition, the air conditioner of an Example is controlled by the said control apparatus based on the temperature and humidity of outdoor air.

Thereby, dew point temperature can be grasped | ascertained by methods, such as calculation. As a result, the temperature of the heat absorbing surface can be controlled to be equal to or lower than the dew point of the suction outside air, and an air conditioner capable of reliably condensing moisture and supplying it to the electrostatic misting device can be provided.

In addition, when the Peltier element 441 is operated when the intake air is low temperature, water in the intake air is condensed on the heat absorption surface, and water droplets trapped on the wall surface of the downstream flow exit 331 near the heat absorption surface become frost and freeze. There is a case to do it. Depending on the conditions of the outside air, this frost may be melted by the classified outdoor air passing through the heat absorbing surface and fall to the absorbent water conveying member 423a. However, when the conditions of the outside air are bad, the frost remains unmelted. Under these conditions, if the Peltier element 441 continues to operate, the condensed water to be absorbed by the absorbent water conveying member 423a freezes on the wall of the fractional outlet air passage 331, so that the water of the water to the absorbent water conveying member 423a is retained. The replenishment stops, the supply of water for misting is stopped, and electrostatic misting is not performed. In addition, the frost grows, and the air path is closed, which prevents ventilation of outside air serving as a water source.

In order to escape from this state, in the embodiment, the operation of the Peltier element 441 is stopped when the first predetermined time (3 hours in the embodiment) has elapsed from the start of the operation of the Peltier element 441.

At this time, when the outside air temperature is high, melting of the freezing is promoted by passing the outside air through the heat absorbing portion. On the contrary, when the outside air temperature is low, the above-described classifier outdoor air damper is closed so that the low-temperature classifier outside air does not enter the heat absorbing portion and prevent the melting of freezing.

As a result, the thawing around the heat absorbing portion proceeds, and the operation of the Peltier element 441 is resumed at the time point when the second predetermined time (1 hour in the embodiment) has elapsed from the stop, and the extraction operation of the mist water in the air is continued.

In addition, since the 1st and 2nd predetermined time change with the performance of the Peltier element 441, the dimension of the heat absorbing surface, the quantity of classified outside air, etc., it is good to determine, confirming by experiment by a prototype.

Further, the air conditioner of the embodiment stops the operation of the water generation cooling apparatus when the first predetermined time elapses from the start of operation of the water generation cooling apparatus, and generates the water when the second predetermined time elapses from the stop. Start the cooling device for operation.

Thus, even when the outside air temperature is low, the operation of the water generation cooling apparatus is stopped when a predetermined time comes from the start of the operation of the water generation cooling apparatus. By doing so, the endotherm of the downstream heat exchange surface, which was the endothermic surface, is stopped during operation of the water generating cooling device, and the surroundings are warmed by the movement of heat from the indoor air, which is captured and frozen on the wall surface of the fractional outlet air passage 331. Frost also warms up and melts. The frost which melt | dissolved and becomes water flows to the absorbent water conveyance member 423a, and is supplied to an electrostatic mist-forming apparatus. In addition, the frost melts and the air path is opened to allow ventilation of the outside air.

In addition, when the outside air temperature is 0 degrees or higher, the frost melts even in the classified outside air, so that the melting of the frost proceeds rapidly, the time until the end of the melting is shortened, and the operation rate of the water generating cooling device is increased, Increase the amount of fire water obtained.

This can provide an air conditioner capable of supplying water for misting even when the outside temperature is low.

In addition, the air conditioner of the embodiment has a jet external air damper for controlling the ventilation to the heat absorbing surface of the water generating cooling device, and closes the jet external air damper when the outside air temperature is below a predetermined temperature.

As a result, the classified outdoor air classified from the low-temperature intake air is blocked, and the fusion of the frost is not hindered by the low-temperature intake air, and the frost is reliably advanced by heat transfer from the indoor air. It is possible to operate the cooling device for producing water for obtaining water. In the Example, when this predetermined temperature was made +3 degreeC, the favorable thawing result was obtained. As a result, it is possible to provide an air conditioner capable of securing a long driving time for acquiring water for fog from the outside air.

Further, the air conditioner of the embodiment is formed in a tubular shape of the cooling means 425 of the water generating cooling device for generating the water for electrostatic mist, and a part of the cylindrical outer surface heat exchange with the low temperature portion of the water generating cooling device. The inner surface of the cylindrical cooling means 425 is a heat exchange surface with the suction outside air, and condenses moisture in the outside air.

It is said that the water of the electrified mist fine grain floating in the room evaporates to the surrounding air and finally disappears, but the above action takes place until it disappears. Long is preferred.

According to the air conditioner of the embodiment, the moisture of the outside air is continuously condensed, and the condensed water is continuously supplied to the misting part of the electrostatic misting device through the frequency passage, and a sufficient amount of the charged misting fine granules flows into the room. This can deodorize the room continuously.

Therefore, not only is it unnecessary to devise a proper time for supplying water for electrostatic fog, but it is also unnecessary to supply water, and the amount of water for electrostatic fog can be increased efficiently.

In addition, since moisture is obtained from inhaled outside air, the humidity in the room is less likely to drop and may be slightly increased. Since the humidity may be difficult to increase or slightly higher, the evaporation of the water of the finely fogged fine grains is suppressed than before, and the time until extinction is longer. This makes it possible to reach farther and have a deodorizing effect over a wider range.

Moreover, the air conditioner of an Example forms the fin on the inner surface of the said cylindrical cooling means 425, and performs super water-repellent treatment on the heat exchange surface which condenses the moisture in air by contacting at least air of this cooling means 425. Doing. Moreover, the heat exchange surface with room air is provided in the other part of the said outer surface of the cylindrical cooling means 425.

Specifically, the tubular endothermic surface is connected to the air flow path for the classification outdoor air, and the classification outdoor air flows inside. On the other hand, a part of the outer surface of the cylindrical shape is formed in a plane to be in close contact with the low temperature portion of the cooling device for generating water, and most of the other surface to face the indoor air. By doing so, the heat of the sorted outside air flows into the tubular outer surface closely contacted with the low temperature part of the water generating cooling device → the cold part of the water generating cooling device, and the heat of the sorted outside air is taken away and the moisture of the sorted outside air is lost. Is condensed.

On the other hand, the heat of the surrounding indoor air flows to the low temperature part of the cylindrical outer surface → water generating cooling device which is in close contact with the low temperature part of the indoor air → the cylindrical outer surface → the water generating cooling device, and the heat of the surrounding indoor air is deprived. Moisture in the air condenses. Thus, by providing a cylindrical heat absorbing surface and using both inner and outer surfaces intricately, the heat of both the sorted air and the surrounding indoor air can be absorbed at the low temperature portion of the cooling device for generating water.

In addition, the moisture in the suction outside air cooled by the heat absorbing surface condenses on the heat absorbing surface, but since the heat absorbing surface is subjected to super water repellent treatment, the contacted heat exchange surface (super water repellent surface) falls down or bounces off the super water repellent surface. It floats in airflow, flows downstream with airflow, or is divided into either state.

Leaving the water droplets downstream, as it is, unnecessarily flows out of the exhaust port with the airflow to the outside, or takes heat into the surrounding airflow while flowing with the airflow, and does not evaporate into misting water. In order to prevent this, it is necessary to devise the absorbent water conveying member 423a as water droplets immediately after the moisture is condensed.

Very small water droplets floating in a mist form coalesce and grow in contact with other water droplets in the air stream. This larger water droplet is more strongly affected by gravity than by airflow. As a result, a speed difference with the airflow occurs, and the chance of coalescing in contact with another very small droplet increases, gradually increasing, falling downward, and absorbed by the absorbent water conveying member 423a.

In addition, the other part is attached in contact with the wall surface having a relatively high hydrophilicity of the air path located downstream of the heat absorbing surface. The water droplets soaked flow down the wall surface of the air path by their own weight and are absorbed by the absorbent water conveying member 423a at the lower portion and move to the electrostatic misting device through the water passage.

When the outside air temperature decreases, the endothermic surface becomes 0 degrees or less, and floating very small droplets are frosted and adhered to the wall of the fractional outlet air passage 331 located downstream of the endothermic surface. At this time, if the temperature of the fractionated outdoor air passing through the endothermic surface is 0 degrees or more, frost attached to the wall of the fractional outlet air passage 331 is melted, and the wall of the fractional outlet air passage 331 flows down to the absorbent water conveying member 423a. It is absorbed and becomes the mist water. Thus, even if the endothermic surface freezes, the water for misting can be obtained from the wall of the downstream flow outlet 331, so that the water for misting can be supplied even at the low temperature and the low humidity side of the outside air. .

Here, the behavior of the suction outside air flowing into the cooling means 425 will be described. The outside air sucked into the heat absorbing surface of the cylindrical inner surface hits the end surface of the fin at the inlet portion of the heat absorbing surface, is disturbed and divided into the cylindrical shape. The airflow that has entered the cylindrical shape is in contact with the heat absorbing surface, and water in the airflow condenses. Condensed water droplets try to adhere to the super-water surface, but most of the water droplets are bounced off and pushed into the air stream to become 10 μm in diameter and flow with the air stream. At this time, since the airflow is disturbed, the water droplets in the airflow also come into contact with each other, increasing the chance of coalescing by contacting and coalescing, and the larger water droplets fall downward due to gravity, and the small droplets that come later collide with the large water droplets that fall. It gradually increases in size.

The water droplets falling and falling on the fins flow down the inner wall face down or are pushed by the airflow to roll the pins downstream, and then jump out from the downstream end of the fin to the exit air passage and fall down on the bottom of the outlet air passage to be installed downward. It flows into the water conveyance member 423a and is absorbed.

In addition, water that has passed through the endothermic surface of the duct-type with airflow as small droplets is disturbed by the airflow again at the outlet end of the fin, so that the chance of contact with other droplets and coalescence increases again to become large droplets. It falls to the bottom face of the exit air path, flows, and is absorbed by the absorbent water conveying member 423a. In this way, the water droplets spaced apart from the water-repellent surface and float in a fog shape are enlarged by contacting and coalescing with each other.

As a result, it is unnecessary to supply water from the outside to the electrostatic fog device, and the water for electrostatic fog can be obtained from both outdoor air and indoor air. In addition, it is possible to provide an air conditioner capable of efficiently collecting floating water droplets spaced apart from the super water-repellent surface and supplying it as misting water, and expanding the temperature and humidity conditions of the outside air that can supply water to the misting portion to the low temperature side. have.

In the embodiment, the pin is installed on two opposite surfaces of the cylindrical inner air passage, and the straight line connecting the tip of the pin on one side connects the tip of the pin on the opposite side to the straight line connecting the base of the pin. It's in the middle of a straight line.

As a result, a portion without pins is generated in the middle of the two opposing surfaces, and a difference is generated in the speed and direction flowing between the airflow flowing through this portion and the airflow flowing between the fins, and the flow is disturbed. Thereby, the disturbance of the airflow inside a cylindrical shape becomes large, the chance of contact of droplets increases, and the collection efficiency of the condensed water rises. In addition, the water droplets enlarged in the airflow can freely fall.

The embodiment makes the average height of the fin on the side closer to the low temperature part heat exchanger surface among the two opposing surfaces higher than the average height of the fin on the opposite side.

In general, the fin on the side near the low temperature part has a short distance to the low temperature part, so the thermal resistance is low, and the temperature of the fin is low. On the contrary, the fin on the side farther away from the low temperature part has a long distance to the low temperature part. It is big and the temperature of a pin becomes high.

According to the air conditioner of the embodiment, in the fin near the low temperature part, the total heat area increases, and the heat exchange amount also increases, thereby increasing the temperature of the fin. On the contrary, in the fin located far from the low temperature portion, the total heat area decreases, the heat exchange amount also decreases, and the fin temperature decreases.

For this reason, the temperature of a fin surface is averaged and the air conditioner which can make a cylindrical heat absorbing surface small by the amount which heat exchange amount increases can be provided.

According to the embodiment, an outlet air passage in which the classified outdoor air flows upward is disposed downstream of the endothermic surface of the cooling means 425, and a water conveyance repairing means is provided below the bottom of the outlet air passage to prevent the water from the water conveying repairing means. It allows water to travel along the path.

As a result, the difference in the velocity of the droplets having different sizes in the airflow increases, and the rapid droplets collide with the slow droplets and coalesce. The water droplets increase in size due to the coalescence of the water droplets, and the influence of gravity on the water droplets overcomes the airflow and falls. The dropped water drops are inclined by the inclined surface of the exit air path and are absorbed by the water conveyance repairing means. Moreover, the water droplets collected on the wall of the outlet air passage are also absorbed by the water conveyance repairing means provided below the wall of the outlet air passage. As a result, the amount of the water exhausted while floating in the airflow decreases, and the amount of water absorbed by the water return repair means increases. As a result, the electrostatic misting device or air conditioner can recover condensed water efficiently, and can shorten the operating time of the water generating cooling device or realize energy saving by making the water generating cooling device small and using small power. Groups can be provided.

In addition, in the embodiment, the classifying outside air path is provided in which the classifying outside air flows downward from the endothermic surface of the cooling means 425.

As a result, when the outside air flows into the cooling means 425, the airflow of the downward velocity component collides with and crosses the distal end portion of the fin, and the airflow flowing through the central wind path flows downwardly by the downward velocity component. Different flows affect each other and are greatly disturbed.

This increases the chance of contacting and coalescing droplets contained in the air stream, thereby providing an air conditioner capable of efficiently recovering the water in the condensed fractional outdoor air to the water return and repair means 423.

Next, the automatic cleaning apparatus with which an Example is provided is demonstrated using FIG. 2, FIG. 5, FIG. 8, FIG. 16, FIG. An upper suction part 230 and a front suction part 230 ′ are formed upstream of the indoor heat exchanger. The upper suction part 230 is arrange | positioned substantially horizontally, and the front suction part 230 'is arrange | positioned substantially vertically, and these comprise the two orthogonal surface of the indoor unit 2, and so on. Planar filters 231 and 231 'are provided in the upper suction part 230 and the front suction part 230'.

In addition, when the part which has the same function exists for the upper filter 231 and the front filter 231 ', the code | symbol of the part for the upper filter 231 is attached to the part for the front filter 231'. Distinguish by attaching "".

As such, the dust on the filter 231 'is swept away by the cleaning brush installed in the brush support frame 262' to reach the vibration damping brush 270 'at the left end, and scraped off by the vibration damping brush 270'. The dust is dropped from the dust hopper 281 to the dust collecting box 284 and collected. In this way, the dust is collected by the dust collecting box 284 and never returned to the outside.

The dust filter box 284 is provided with the above-mentioned outside air filter housing 284b at the rear portion of the dust storage unit 284a, and is partitioned between the dust collecting boxes 284 by partition means, and the partition seal is removed from the dust hopper 281. By contact | adhering to the division opening 281c, the accommodating part 284b and the removal dust storage part 284a of the outside air filter 325b are completely interrupted | blocked.

The dust collection box 284 is provided with the accommodating part 284b of the outside air filter 325b as mentioned above later, and the front half becomes the storage part 284a of the removal dust. The front wall of the storage portion 284a has a cover portion that blocks aeration from the room, and the surrounding portion of the storage portion 284a is in close contact with the removal dust discharge port by the cover portion seal to prevent the dust of the removal dust storage portion 284a from scattering to the interior. have.

In general, when the crossflow fan is operated in a state with low ventilation resistance, the crossflow fan generates airflow with almost no confusion in the axial direction, and can reach the airflow to a far place. On the other hand, in the case of operating with a large ventilation resistance on the suction side, the reverse flow easily occurs in the blowing air passage 290 around the terminal in the axial direction. When such a backflow occurs, the airflow is disturbed to increase noise, and the uniformity in the axial direction of the airflow is impaired, making it difficult to reach the far airflow. For this reason, it is necessary to clean the filters 231 and 231 'regularly.

To start the cleaning operation of the automatic cleaning device, the condition of the predetermined filter cleaning operation, for example, the cumulative operation time of the cross flow fan 311 exceeds the time from the last cleaning execution (30), and immediately before The cleaning operation starts when the condition of the crossflow fan 31l is satisfied for 10 minutes or more in the operation of.

By controlling in this way, since the filter 231 'is always kept in a state with little dust, the performance deterioration of the heat exchanger 33 resulting from the contamination of the filter 231', and the backflow of the crossflow crossflow fan ejection part can be prevented. . As a result, the charged fine grain water generated by the electrostatic misting device 42 is carried in the rectified airflow of the crossflow type crossflow fan to be transported to a far place in the room, and the deodorizing action of the charged fine grain water is spread over a wide range of rooms. Can be expressed.

When dust in the dust collecting box 284 is discarded, the dust collecting box 284 is removed and the dust inside is scraped off. According to the embodiment, in this way, the interior of the room can be kept comfortable and clean in accordance with the improvement of the air quality by the electrostatic misting device 42.

Next, the cleaning of the removal dust storage unit 284a and the cleaning and replacement of the air filter 325b will be described with reference to FIGS. 6, 16, and 17.

When the air conditioner is operated and a long time elapses, the repetitive filters 231 and 231 'are cleaned, and the dust removed in the removal dust storage unit 284a is accumulated. In addition, if the outside air suction operation is performed for a long time, dust is accumulated on the outside air filter 325b, and the amount of charge decreases, and the dust collection effect is lowered.

For this reason, when used in a dust-rich environment, it is necessary to clean the removal dust storage part 284a, the cleaning of the air filter 325b, and replacement once every 2 to 3 years if it is short. In the embodiment, the storage part 284b of the air filter 325b is coupled to the removal dust storage part 284a. When cleaning the dust removal unit 284a, cleaning or replacing the air filter 325b, the front panel 25 is opened as shown in the dotted line in Fig. 6, while holding the handle portion 284c of the lid portion 284n. The lead is removed from the indoor unit 2 and removed. The removal dust storage part 284a of the removed dust collecting box 284 is cleaned, and the external air filter 327b of the accommodating part 284b is checked, and a cleaning or replacement is performed.

Next, the dust collecting box 284 is inserted and installed in the indoor unit 2, and the front panel 25 is closed to finish the maintenance of the removal dust storage unit 284a and the outside air filter 325b. In this way, the opening for maintenance is integrated by integrating two other functional components, namely, the storage portion 284b of the outside air filter 325b of the outside air suction mechanism 32 and the removal dust storage portion 284a of the cleaning device 240. It can be shared and space can be saved. In addition, by cleaning the integrated parts, it is possible to simultaneously maintain the other two functions.

In this way, the replacement and removal of the air filter 325b and the cleaning of the dust storage unit 284a can be performed by detaching only the dust collecting box 284 and at the same time the high temperature portion of the Peltier element 441 of the electrostatic misting device 42. The distance between the 444 and the outside air suction mechanism 32 is close, so that the heat sink 338 of the Peltier element 441 can be easily cooled by the suction outside air of the outside air suction mechanism 32.

Second Embodiment

In the second embodiment, a temperature sensor is provided at a low temperature portion of the Peltier element 441 so that the supply of water for misting can be ensured even when the outside air temperature is particularly low.

In the embodiment, the first predetermined time (30 minutes in the embodiment) or more elapses from the start of operation of the Peltier element 441, and the temperature of the low temperature portion of the Peltier element 441 is lower than or equal to the first predetermined value (-6 ° C in the embodiment). In this case, it is determined that the freezing of the endothermic portion of the Peltier element 441 needs to be melted, and the operation of the Peltier element 441 is stopped.

At this time, when the outside air temperature is high, melting of the ice is promoted by passing the fractionating outside air through the heat absorbing portion. On the contrary, when the outside air temperature is low, the above-described classifier outdoor air damper is closed so that the low-temperature classifier outside air does not enter the heat absorbing portion and prevent the melting of freezing.

As a result, the thawing around the heat absorbing portion advances and the operation of the Peltier element 441 resumes when the temperature of the low temperature portion of the Peltier element 441 becomes higher than or equal to the second predetermined value (4 ° C in the embodiment). The extraction operation in the air of the mist water is continued. When the outside air temperature is particularly low, the temperature of the low temperature portion of the Peltier element 441 may not be higher than or equal to the second predetermined value. In preparation for such a situation, the operation of the Peltier element 441 is resumed when the above-mentioned operation stop for thawing becomes more than a second predetermined time (7 minutes in the embodiment). At this time, it is difficult to say that the supply of water for misting is performed smoothly, but since part of the ice melts during the stop of the Peltier element 441 and falls on the absorbent water conveying member 423a, the supply of water for misting can be continued.

In addition, since the 1st and 2nd predetermined values and the 1st and 2nd predetermined time vary with the performance of the Peltier element 441, the dimension of the heat absorbing surface, the quantity of classified outside air, etc., it is decided to confirm by experimenting with a prototype etc. good.

Thus, the air conditioner of an Example installs a temperature sensor in a downstream heat exchange part, and operates the said water generation cooling apparatus when the temperature which the said temperature sensor shows during operation | movement of the said water generation cooling apparatus is below a 1st predetermined value. Stop.

Thereby, even in such a condition, operation | movement of the water generating cooling apparatus is stopped by the signal from said temperature sensor. By doing so, the endotherm of the downstream heat exchange surface, which was the heat absorbing surface, at the time of operation of the water generating cooling device is stopped, and the surroundings are warmed by the movement of heat from the indoor air, which is captured by the wall surface of the fractional outlet air passage 331 and frozen. Frost also warms up and melts. The frost which melted and became water flows down and flows to the absorbent water conveying member 423a, and is supplied to the electrostatic fogizer. In addition, frost is melted, and the air path is opened to allow ventilation of the outside air.

In addition, when the outside air temperature is 0 degrees or higher, the frost melts even in the classified outside air, so that the melting of the frost proceeds rapidly and the time until the end of the melting is shortened. Increases.

In addition, when the outside air temperature is high, the periphery of the heat absorbing surface does not freeze, and the temperature sensor does not fall below the first predetermined value, operation of the water generation cooling device is continued to supply sufficient misting water.

As a result, it is possible to provide an air conditioner in which the supply of water for misting at a high temperature is smooth and the supply of water for misting is possible even at a low outside temperature.

Further, the air conditioner of the embodiment prohibits the stop for thawing of the cooling apparatus for water generation for the first predetermined time from the stop for the last thaw.

As a result, when the outside air temperature is not so high, the temperature of the outside air is not high, and the temperature of the heat absorbing surface immediately becomes 0 degrees or less immediately after the operation of the water generating cooling device is started. Even when an implantation occurs on the wall of the wall, the water in the classified outdoor air is implanted on the wall of the fractional outlet air passage 331 downstream of the heat absorbing surface before the classified outdoor air path is closed by the concept and the classified outdoor air does not flow. Obtained in form. As such, during the first predetermined time from the last stop for thawing, the stop for thawing is prohibited, and the water discharged from the jet outside air is discharged to the jet exit outlet 331 downstream of the endothermic surface by operating the cooling device for generating water. It condenses as a freeze on the wall and secures it for fog. This freezing is melted at the next stop for thawing and dropped on the absorbent water conveying member 423a to be used as water for misting.

As a result, it is possible to provide an air conditioner capable of securing water for misting the electrostatic misting device even when the outside temperature is low.

Thus, the air conditioner of an Example becomes a state in which the temperature which the temperature sensor provided in the said downstream side heat exchange part is lower than a 1st predetermined value, and the said temperature sensor is made into the 1st temperature when the cooling device for water generation stops operation | movement. When it becomes more than 2nd predetermined value higher than a predetermined value, the said water generation cooling apparatus is operated. As a result, condensation from the suction outside air to the downstream heat exchange surface is started again, and water for misting can be supplied again. In this way, the operation and the stop of the cooling device for generating water are alternately performed. Thus, even when the outside air temperature is low, it is possible to provide an air conditioner that can continuously supply misting water.

Further, the air conditioner of the embodiment is in a state where the temperature indicated by the temperature sensor installed in the downstream heat exchange unit is lower than the first predetermined value, and when the second predetermined time elapses while the water generation cooling device is stopped, Operate the cooling system for water generation.

Thereby, especially when the outside air temperature is low and the melting during the frosting is not completely completed, melting of the frost partially proceeds while the cooling device for water generation is stopped, and the melted water flows to absorb the absorbent water conveying member. Since it falls to 423a, this melted water can be used as water for misting. As a result, it is possible to provide an air conditioner that enables the supply of water for misting, especially when the outside air temperature is low.

1 is a configuration diagram of an air conditioner of an embodiment.

Fig. 2 is a side sectional view of the indoor unit of the air conditioner.

3 is a schematic diagram showing the configuration of an electrostatic fogizer of the indoor unit;

Fig. 4 is an explanatory diagram showing the air flow paths flowing through the water generating unit of the electrostatic fogizer.

Fig. 5 is a perspective view of the indoor unit with the makeup frame removed and viewed from the left side;

Fig. 6 is a sectional view of the indoor unit in which the outdoor air suction mechanism of the indoor unit is seen from the left side;

Fig. 7 is a perspective view of the outside air suction mechanism from the back side;

Fig. 8 is a sectional view of the indoor unit as seen from the right side of the outside air intake mechanism.

Fig. 9 is a perspective view of the outside air suction mechanism unit and the electrostatic misting device as viewed from the front;

Fig. 10 is a perspective view of cooling means of the electrostatic fogizer.

11 is an enlarged view of the cooling means.

12 is a perspective view of a cooling means portion of the water generating portion of the electrostatic misting device;

Fig. 13 is a sectional view taken along the line C-C in Fig. 14;

14 is a side sectional view of the same cooling means.

Fig. 15 is a sectional perspective view showing the inside of the animal generating unit.

Fig. 16 is an exploded perspective view of the Peltier element heat dissipation unit of the animal generating unit.

Fig. 17 is a perspective view of the front panel of the indoor unit removed.

<Explanation of symbols for the main parts of the drawings>

1: air conditioner

2: indoor unit

5: remote control

6: outdoor unit

8: connection piping

20: housing

21: housing base

23: makeup frame

25: front panel

27: air intake

29 air outlet

32: outside air suction mechanism

33: indoor heat exchanger

35: condensation

37: drain piping

38: exhaust air path

39: outside air path

42: electrostatic misting device

230, 230 ': air intake

231, 231 ': filter

251: Movable Panel

262, 262 ': sole support frame

270, 270 ': Dust Removal Brush

281: Remove the dust hopper

281c: compartment opening

284 dust collecting box

284a: removal dust reservoir

284b: air filter housing

284c: Holding part

290: blow-out cooker

290c: Blowout Furnace Sidewalls

291: up and down wind direction plate

295: left and right wind direction plate

311: cross flow fan

313: blower motor

321: outside air suction fan

325: outside air suction device inlet

325b: air filter

326: outside air suction mechanism outlet

328: air intake air duct

328c: Outdoor air passage connection

329: Categorized Outside Airway

329a: Classification outside air intake

329b: Classified External Damper

329c: Damper driven motor

329d, 331d: boss

33l: Classified Exit

333 classification air outlet

338: air duct heat sink

338a: air path heat sink

338b: ambient heat sink fins

341: ambient air path

343: the wall of the surrounding furnace

422 fog electrode

422a: fog mist

422b: Frequency Division

423: water return repair means

423a: absorbent water conveying member

423b: Repair Material for Water Supply

423c: tubular water conveying member

424 fog connection

425 cooling means (cooling block)

425a: cooling wall a

425b: cooling wall b

425c: internal air path

425d: receiving portion of water conveying member

425e: pin a

425f: pin b

425g: central air path

425h: mounting hole

428 ion electrode

429: Conductor

430: discharge part

431: Misty Housing

440: water generator

441: Peltier element

442: low temperature part

443: Insulation Sheet

444 high temperature part

450: high voltage generator

451 high voltage terminal

452: ground terminal

Claims (19)

delete delete delete delete delete delete delete An air conditioner having a blower fan that blows air into a heat exchanger and blows air into a room, the air conditioner comprising: an outside air suction mechanism, an electrostatic mist eliminating device, a Peltier element for cooling the suction outside air sucked by the outside air suction mechanism, and It has a frequency path leading the condensation water obtained from the Peltier element to the mist of the electrostatic mist, The temperature of the heat absorbing surface of the Peltier element is controlled to be below the dew point temperature of the outside air, The air conditioner is characterized by not ventilating the heat absorbing surface of the Peltier element when the outside air temperature is below a predetermined temperature. An air conditioner having a blower fan that blows air into a heat exchanger and blows air into a room, the air conditioner comprising: an outside air suction mechanism, an electrostatic mist eliminating device, a Peltier element for cooling the suction outside air sucked by the outside air suction mechanism, and It has a frequency path leading the condensation water obtained from the Peltier element to the mist of the electrostatic mist, A temperature sensor is provided in a downstream heat exchanger, and the Peltier element is stopped when the temperature indicated by the temperature sensor is equal to or less than a first predetermined value while the Peltier element is in operation. The air conditioner according to claim 9, wherein the stopping of the Peltier element is prohibited for a first predetermined time from the last stop. delete delete delete delete delete delete delete delete delete

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