KR20100073206A - Washing apparatus of air conditioner and method for controlling the same - Google Patents

Abstract

PURPOSE: A washing apparatus for an air conditioner and a control method thereof are provided to restrict that electrolyte is provided to water which does not require the supply of electrolyte by determining the kind of water stored in a storage and automatically supplying the electrolyte according to the determined result. CONSTITUTION: A washing apparatus for an air-conditioner comprises: an electrolyte supply unit(44) which includes an electrolyte receive unit which stores electrolyte and includes a first hole discharging electrolyte, a rotary panel which is rotatably installed to the outside of the electrolyte receive unit and opens and closes the first hole, and a motor which rotates the rotation panel; a storage which stores water; an electrolysis unit(42) which electrolyzes the water with supplying water from the storage; and a controller which determines whether the water supplied from the electrolysis unit is the electrolyte dissolved water or not and controls the motor to control the discharge of the electrolyte according to the determined result.

Description

Washing apparatus of air conditioner and method for controlling the same}

The present invention relates to a washing apparatus and a control method of the air conditioner, and more particularly to a washing apparatus and a control method of the air conditioner for washing and sterilizing dust, foreign matter and bacteria of the heat exchanger.

In general, an air conditioner is a device that cools, heats or purifies an intake air by discharging the refrigerant by evaporating and condensing it, and then discharging the air to harmonize air in a specific space. A compressor for converting to a high pressure state, a condenser for releasing internal latent heat to the outside while converting the high temperature and high pressure refrigerant compressed by the compressor into a liquid phase, and expansion means for reducing pressure by controlling the flow rate of the refrigerant converted into a liquid phase from the condenser; In addition, the evaporator absorbs external heat while evaporating the liquid refrigerant expanded in the expansion means into a gas, and each component is connected by a connection pipe. If the air conditioner is not used for a long time, dust, bacteria, water, etc. are generated on the surface of the heat exchanger such as a condenser or evaporator, and the thermal efficiency is lowered when the heat exchanger is driven by such dust, bacteria, and water. Water causes an unpleasant odor when the heat exchanger is running.

As a result, washing to remove dust, bacteria, water, etc. of the heat exchanger of the air conditioner is performed. At this time, there is a hassle that the user has to manually wash by dismantling and separating the heat exchanger. Or when the dust, bacteria, water, etc. of the heat exchanger of the air conditioner occurs, the heat exchanger itself is replaced, at this time labor and exchange costs incurred by the exchange of the heat exchanger. In addition, the heat exchanger of the air conditioner is not only easy to separate and clean the heat exchanger according to the installation place and installation method, but also to replace the heat exchanger itself in a limited space.

According to an aspect of the present invention, the electrolyte receiving portion is formed with a first hole in which the electrolyte is accommodated and the electrolyte is discharged, a rotating panel rotatably installed outside the electrolyte receiving portion to open and close the first hole, and rotating the rotating panel An electrolyte supply unit having a motor; A storage unit for storing water; An electrolysis unit that receives water from the storage unit and electrolyzes the water; It is determined whether the water supplied to the electrolysis unit is dissolved electrolyte, and the control unit for controlling the discharge of the electrolyte by controlling the motor according to the determined result.

Here, the rotating panel has a second hole provided at a position corresponding to the position of the first hole, and the control unit rotates the motor so that the position of the second hole of the rotating panel coincides with the position of the first hole.

Here the motor has a rotating shaft, the rotating panel has a shaft insertion portion is inserted into the rotating shaft.

The electrolyte container further includes a cover for fixing the fixing protrusion and sealing the electrolyte container from the outside.

The electrolyte here is a spherical solid electrolyte.

And the bottom surface of the electrolyte receiving portion is inclined from the center to the outside.

The electrolyte accommodating portion has a guide portion for guiding the electrolyte to the first hole.

The guide unit is a cleaning device for an air conditioner formed in a spiral shape.

The electronic device may further include a hole detector configured to detect a position of the second hole of the rotation panel, and the controller may control the rotation of the motor according to the detection signal of the second hole transmitted from the hall detector.

The electrolyte supply unit is provided above the storage unit.

The apparatus may further include a current sensing unit configured to sense a current flowing in the water accommodated in the electrolysis unit, and the controller may determine whether the electrolyte is discharged by comparing the sensed current with the reference current.

And an injection unit for injecting water electrolyzed in the electrolysis unit to a heat exchanger.

The water level detector may further include a water level detector configured to detect a water level of the water stored in the storage unit.

The water in the reservoir is water in which condensate generated in the heat exchanger is stored.

Or a supply hole provided in a cabinet forming an exterior of the air conditioner, wherein the water in the storage unit is water supplied by the user through the supply hole.

According to another aspect of the present invention, the electrolyte receiving portion is formed with a first hole in which the electrolyte is received and the electrolyte is discharged, a rotating panel rotatably installed outside the electrolyte receiving portion to open and close the first hole, and rotating the rotating panel An electrolyte supply unit having a motor; A control unit controlling the motor to discharge the electrolyte when the heat exchanger is cleaned; A storage unit storing water generated when the heat exchanger is driven and generating electrolyte dissolved water when the electrolyte is discharged; An electrolysis unit for electrolyzing the electrolyte dissolved water; And an injection unit for injecting the electrolyzed water into the heat exchanger.

And a current sensing unit for sensing a current flowing in the electrolyte dissolved water contained in the electrolysis unit, and the controller controls the additional discharge of the electrolyte by comparing the sensed current with the reference current.

Here, the rotating panel has a second hole provided at a position corresponding to the position of the first hole, and the control unit rotates the motor so that the position of the second hole of the rotating panel coincides with the position of the first hole.

And further comprising a hole sensing unit for detecting the position of the second hole of the rotation panel, the control unit controls the rotation of the motor in accordance with the detection signal of the second hole transmitted from the hall detection unit.

Here the motor has a rotating shaft, the rotating panel has a shaft insertion portion is inserted into the rotating shaft.

And the bottom surface of the electrolyte receiving portion is inclined from the center to the outside.

The electrolyte accommodating portion has a spiral guide portion for guiding the electrolyte to the first hole.

The electrolyte accommodating portion has at least one fixing protrusion on the outer circumferential surface thereof, and an insertion hole into which the fixing protrusion is inserted and mounted is formed, and further includes a cover for fixing the electrolyte accommodating portion and sealing it from the outside.

According to another aspect of the present invention, the water stored in the storage unit is supplied to the electrolysis unit, it is determined whether the water supplied to the electrolysis unit is the electrolyte dissolved water, and according to the determined result to control the motor to rotate the rotating panel, The opening and closing of the first hole of the electrolyte accommodating part is controlled by the rotation of the rotating panel to regulate the discharge of the electrolyte in the storage part.

And if the water supplied from the storage portion is the electrolyte dissolved water electrolytic decomposition of the electrolyte dissolved water to generate the washing water, and spraying the washing water to the heat exchanger further comprises washing the heat exchanger.

And when the washing of the heat exchanger is completed, discharging the washing water to the outside.

And to determine whether the electrolyte dissolved water, the current flowing in the water accommodated in the electrolysis unit senses, and compares the detected current and the reference current.

And supplying water to the electrolysis unit further includes supplying water to the electrolysis unit if the storage level is a reference level.

And sensing the current flowing in the water accommodated in the electrolysis unit, comparing the current with the reference current, and controlling additional discharge of the electrolyte according to the compared result.

The water generated in the heat exchanger is stored in a storage unit, the motor rotates when the heat exchanger is cleaned to rotate the rotating panel, the first hole of the electrolyte receiving part is opened according to the rotation of the rotating panel, and the opened first hole. The electrolyte is discharged through the storage unit, and when the electrolyte is dissolved in water in the storage unit and the electrolyte is dissolved in water, the electrolyte is supplied to the electrolysis unit, and the electrolyte dissolved water is electrolyzed and sprayed into the heat exchanger.

And it detects the current flowing in the electrolyte dissolved water supplied to the electrolytic part, and if the detected current is less than the reference current to control the further discharge of the electrolyte.

And opening the first hole coincides with the position of the first hole of the electrolyte accommodating part and the position of the second hole of the rotating panel.

According to an aspect of the present invention, by determining the type of water stored in the storage unit and automatically supplying the electrolyte according to the determination result, it is possible to limit the supply of electrolyte in the water that does not require the supply of the electrolyte.

According to another aspect of the present invention, by controlling the supply amount of the electrolyte, it is possible to increase the efficiency of electrolysis because the electrolyzed water in which the appropriate amount of the electrolyte is dissolved. In addition, by spraying the acid and alkaline water generated during the electrolysis to the heat exchanger, it is possible to efficiently wash and sterilize dust, scale, bacteria, etc. collected in the heat exchanger of the air conditioner.

In addition, it is possible to clean the heat exchanger without disassembling and separating the heat exchanger, so that the heat exchanger can be easily washed, and the continuous performance of the heat exchanger can be maintained, thereby improving heat exchange efficiency and saving energy.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is an external perspective view of an air conditioner according to an embodiment of the present invention, FIG. 2 is an internal perspective view of an air conditioner according to an embodiment of the present invention, and FIG. 3 is provided in an air conditioner according to an embodiment of the present invention. 4 is a detailed perspective view of the washing apparatus, FIG. 4 is an exploded perspective view of the washing apparatus according to the embodiment of the present invention, and FIG. 5 is a cross-sectional view of the washing apparatus according to the embodiment of the present invention.

As shown in FIG. 1, the air conditioner 10 is provided with a cabinet 11 having an open front face and a front panel 12 covering the entire open front of the cabinet 11 to form an exterior. Discharge openings 13 through which heat-exchanged air is discharged are provided at both upper sides of the cabinet 11, and blades 14 are provided at the discharge openings 13 to guide the flow of discharged air flow, and the lower part of the cabinet 11 is provided. Both sides are provided with a suction port 15 for sucking outside air. In addition, an inlet 50 is formed at one side of the cabinet 11 for supplying water (ie, tap water) to the storage unit, and the inlet 50 has an opening and closing member for opening and closing the inlet 50. Is installed. The inner space of the cabinet 11 is partitioned into a lower blower installation chamber and an upper heat exchanger installation chamber.

As shown in FIG. 2, the blower installation chamber of the cabinet 11 includes a blowing fan 21 for sucking external air and blowing the sucked air, and a fan motor for applying rotational force to the blowing fan 21 (not shown). And a fan housing 22 accommodating the blower fan 21 and guiding the air sucked through the blower fan 21 to the heat exchanger installation chamber, and the heat exchanger installation chamber is guided through the fan housing 22. The heat exchanger 31 which heat-exchanges with air is provided. Here, the heat exchanger 31 is formed in a flat plate shape so that the air blown from the fan housing 22 can be heat-exchanged while passing therethrough, and is inclined in the inner upper space of the cabinet 11.

As shown in FIG. 2 and FIG. 3, a washing apparatus 40 for washing dust, foreign matter and scale of the heat exchanger 31 and sterilizing bacteria in the heat exchanger 31 in the internal space of the cabinet 11. ) Is provided. The cleaning device 40 includes a storage part 41, an electric part disassembly 42, a drain valve 43, an electrolyte supply part 44, and an injection part 45.

The storage unit 41 is provided at the lower end of the heat exchanger 31 to store the condensed water generated in the heat exchanger 31, and supplies the stored water to the electrolysis unit 42. In addition to storing the condensate generated in the heat exchanger 31, the storage unit 41 may store water (eg, tap water) directly supplied by the user through the inlet 50.

And the storage unit 41 is further provided with a water level detecting unit 110 for detecting the level of water stored therein. In addition, the storage unit 41 is provided with an overflow tube 41a for discharging water to the outside when the water level of the storage unit 41 detected by the water level detecting unit 110 is higher than the reference level.

The electrolysis unit 42 receives water from the storage unit 41 and electrolyzes the water to generate washing water for sterilizing and washing the heat exchanger 31. That is, the electrolysis unit 42 includes a case forming an appearance, a pair of electrode plates installed inside the case, and an ion separation membrane provided between the electrode plates to partition the case. When (+) power and (-) power are applied to each of the pair of electrode plates, ions of water (ie, electrolyte dissolved water) containing electrolyte pass through the ion separation membrane 135, such as acidic water and alkaline water. Washing water is produced.

The electrolysis unit 42 includes a first wash water pipe 42a through which the acidic water generated by electrolysis is moved, and a second wash water pipe 42b through which the alkaline water generated by electrolysis is moved, and the first wash water pipe is provided. A first pump 42c is provided at 42a for moving the acidic water to the first injection part 45a, and a second washing water pipe 42b is provided for moving the alkaline water to the second injection part 45b. Two pumps 42d are provided. In addition, the electrolysis unit 42 is provided with a current detection unit 120 for detecting a current flowing in the water accommodated therein.

The acidic water generated by the electrolysis of the water in the electrolysis unit 42 serves to sterilize the bacteria inhabit the heat exchanger 31, the alkaline water serves to wash the dust accumulated in the heat exchanger (31). Here, the washing water generated by the electrolysis of the electrolysis unit 42 may generate at least one of OH radical water and ozone water in addition to acidic water and alkaline water.

The acidic water and the alkaline water injected into the heat exchanger 31 flow downward along the heat exchanger 31, and are stored in the storage 41 again to be neutralized, and the neutralized water in the storage 41 is transferred to the third pump. It is supplied to the electrolysis part 42 by the drive of 46 again.

The drain valve 43 is installed between the storage unit 41 and the electrolysis unit 42 to supply water from the storage unit 41 to the electrolysis unit 42 or externally store the water in the storage unit 41. To be discharged.

The drain valve 43 is the first valve 43b for opening and closing the first drain pipe 43a provided to drain the condensed water stored in the storage unit 41 when the air conditioner is driven, and the heat exchanger 31 It includes a second valve (43d) for opening and closing the second drain pipe (43c) provided for supplying the water of the storage unit 41 to the electrolysis unit 42 at the time of washing. That is, when the air conditioner is driven, the first valve 43b is opened to drain the condensed water generated by the heat exchanger 31 through the first drain pipe 43a, and when the heat exchanger 31 is washed, The first and second valves 43b and 43d are closed to store the condensed water generated in the heat exchanger 31 in the storage 41 and then supplied to the electrolysis unit 42.

Alternatively, the drain valve 43 connects the storage unit 41 and the first and second valves 43b and 43d, so that the storage unit 41 and the first valve 43b are connected when the air conditioner is driven. In the sterilization of the heat exchanger 31, the three-way valve is switched to connect the storage part 41 and the first valve 43b.

The electrolyte supply part 44 is installed on the upper part of the storage part 41 to supply the electrolyte to the storage part 41 so that water is electrolyzed in the electrolysis part 42 to generate washing water such as acidic water and alkaline water. At this time, the electrolyte is a spherical solid electrolyte.

As shown in FIG. 4 and FIG. 5, the electrolyte supply part 44 has the electrolyte accommodating part 44a, the rotating panel 44b, the electrolyte supply motor 44c, and the cover 44d.

Wherein the electrolyte receiving portion 44a is formed in a cylindrical shape and the electrolyte (e) is accommodated therein, the outer side is formed with a first hole (h1) of the size through which the electrolyte (e) can penetrate The electrolyte e is discharged to the outside through the one hole h1.

A spiral guide portion a1 is provided on the bottom surface of the electrolyte accommodating portion 44a, and the bottom surface of the electrolyte accommodating portion 44a is inclined from the center to the outer side. The electrolyte e is accommodated between the guide portions a1 of the electrolyte accommodating portion 44a, and a first hole h1 is formed between the guide portions a1. Accordingly, the electrolyte e is easily moved from the center to the outer side along the guide part a1, and the electrolyte e that is moved outward is discharged to the outside through the first hole h1.

The electrolyte receiving portion 44a has a plurality of fixing protrusions a2 formed on an outer upper side thereof, and the fixing protrusions a2 are inserted into the cover 44d to fix the electrolyte receiving portion 44a.

The rotating panel 44b is rotatably installed at the outer bottom of the electrolyte accommodating portion 44a. The rotary panel 44b has a shaft insertion portion b1 formed therein, and the rotary shaft c1 of the electrolyte supply motor 44c is inserted and mounted therein, and when the rotary shaft c1 of the electrolyte supply motor 44c is inserted and mounted, the electrolyte supply is performed. While receiving and rotating the rotational force of the motor 44c, the first hole h1 of the electrolyte accommodating portion 44a is opened and closed so that the electrolyte e contained in the electrolyte accommodating portion 44a is moved to the outside through the first hole h1. To be discharged. And the support part b2 is formed in the outer peripheral surface of the rotating panel 44b, and the fixing protrusion a2 of the electrolyte accommodating part 44a is seated on the upper side of this support part b2.

The rotatable panel 44b has a second hole h2 formed on a surface facing the bottom surface of the electrolyte accommodating portion 44a, and has a same size as that of the first hole h1 and corresponds to the first hole h1. Is formed. As a result, when the rotating panel 44b is rotated, the position of the second hole h2 of the rotating panel 44b at one time when the rotating panel 44b is rotated is equal to the first hole h1 of the electrolyte accommodating portion 44a. At this time, the electrolyte e contained in the electrolyte accommodating portion 44a through the first and second holes h1 and h2 is discharged to the outside through the hole h1.

In the electrolyte supply motor 44c, a rotating shaft c1 and a connecting portion c2 are formed. Here, the rotating shaft (c1) is inserted into the shaft insertion portion (b1) of the rotating panel 44b to apply a rotational force to the rotating panel (44b), the connecting portion (c2) is fixedly mounted to the electrolyte supply motor (44c) For this purpose, it is mounted on the upper side of the cover 44d to fix the electrolyte supply motor 44c to the cover 44d.

The cover 44d is for fixing the electrolyte container 44a and sealing it from the outside. The cover 44d is provided with a fixing part d1 to which the electrolyte supply motor 44c is fixedly mounted, and a plurality of inserts into which the plurality of fixing protrusions a2 provided in the electrolyte accommodating part 44a are inserted. The hole d2 is formed.

That is, the electrolyte supply part 44 is provided with the electrolyte receiving portion 44a on the support portion b2 of the rotating panel 44b, and for fixing and sealing the electrolyte receiving portion 44a on the upper side of the electrolyte receiving portion 44a. The cover 44d is installed, and the fixing protrusion a2 is inserted into the insertion hole d2 to be fixed, and the electrolyte supply motor 44c is fixedly mounted on the upper side of the cover 44d. At this time, the through hole is formed in the electrolyte accommodating portion 44a and the cover 44d, and the rotating shaft c1 of the electrolyte supply motor 44c passes through the through hole of the electrolyte accommodating portion 44a and the cover 44d. It is inserted and mounted in the shaft insertion part b1 of the rotation panel 44b.

The injection unit 45 is installed above the heat exchanger 31 to inject the washing water generated by the electrolysis unit 42 to the heat exchanger 31. At this time, the washing water generated in the electrolysis unit 42 is acidic water and alkaline water, and the injection unit 45 receives at least one washing water of acidic water and alkaline water and sprays the heat exchanger 31 by spraying the heat exchanger 31. Sterilize and wash.

The injection unit 45 includes a second injection unit 45a for injecting acidic water into the right region of the heat exchanger 31 and a first injection unit 45b for injecting alkaline water in the left region of the heat exchanger 31. It includes.

And the washing device 40 is installed between the storage unit 41 and the electrolysis unit 42, the third pump 46 for easily supplying the water of the storage unit 41 to the electrolysis unit 42 And a filter unit installed between the third pump 46 and the electrolysis unit 42 to filter water including the water supplied to the electrolysis unit 42 or the electrolyte supplied to the electrolysis unit 42. It further includes (not shown). That is, when water of the reference level is stored in the storage unit 41, the second valve 43d is opened and the third pump 46 is driven to allow the electrolytic unit 42 to pass through the second drain pipe 43b and the filter unit. To supply water.

6 is a control block diagram of the cleaning device provided in the air conditioner according to an embodiment of the present invention, the water level detection unit 110, the current detection unit 120, the control unit 130, drain valve driving unit 140, electrolysis driving unit 150, a pump driving unit 160, an electrolyte supply motor driving unit 170, and a hole sensing unit 180.

The water level detection unit 110 is installed inside the storage unit 41 to detect the water level of the water stored in the storage unit 41, and transmits the detected water level to the controller 130.

The current detecting unit 120 is installed inside the electrolytic unit 42 to detect a current flowing in the water received in the electrolytic unit 44 when power is supplied to the electrolytic unit 42, and the detected current is controlled by the controller ( 130).

The control unit 130 transmits the ON signal of the first valve 43b to the drain valve driving unit 140 when the heat exchanger operates according to the operation of the air conditioner, thereby opening the first valve 43b to open the first heat exchanger 31. The water stored in the storage unit 41 is discharged to the outside according to the heat exchange. The control unit 130 transmits an off signal of the first and second valves 43b and 43d to the drain valve driving unit 140 when the hot air ventilation 31 is washed, thereby closing the first and second valves 43b and 43d. In accordance with the heat exchange of the heat exchanger 31 is stored in the heat exchanger (31) flows into the storage (41).

The controller 130 compares the water level of the storage unit 41 transmitted from the water level detecting unit 110 with a preset reference water level, and if the water level of the storage unit 41 is equal to or higher than the reference water level, the second valve 43d is operated. It is controlled on so that the water stored in the storage unit 41 is supplied to the electrolysis unit 42. The controller 130 compares the current transmitted from the current sensing unit 120 with a preset reference current, and the water stored in the storage unit 41 when the current flowing in the water contained in the electrolysis unit 42 is greater than or equal to the reference current. It is determined that the electrolyte dissolved water to control the operation of the electrolysis unit 42 to perform the electrolysis, if the current flowing in the water contained in the electrolysis unit 42 is less than the reference current water stored in the storage unit 41 Is determined to be condensed water, and the driving of the electrolyte supply motor 44c of the electrolyte supply unit 44 is controlled so that the electrolyte is supplied to the storage unit 41.

That is, the controller 130 determines whether the water stored in the storage unit 41 is condensed water according to the current flowing through the water contained in the electrolysis unit 42. The water stored in the storage unit 41 is stored based on the determination result. If the condensed water formed in the heat exchanger 31 flows down during the heat exchange process of the heat exchanger 31, the electrolyte is supplied to the storage unit 41 every time the heat exchanger 31 is cleaned, while the water stored in the storage unit 41 is stored by the user. In the case of tap water (ie, electrolyte dissolved water) supplied by the electrolyte, the electrolyte is not supplied to the storage part 41 when the heat exchanger 31 is washed. This is because the condensed water generated by the heat exchanger 41 does not contain ions, and the tap water (ie, electrolyte dissolved water) contains ions due to chemicals introduced during the purification process. The controller 41 drives the first and second injection parts 45a and 45b by driving the first and second pumps 42c and 42d to generate the acidic and alkaline water generated during the electrolysis of the electrolysis part 42. Be sure to

The drain valve driving unit 140 transmits on or off of the first and second valves 43b and 43d, respectively, according to the instructions of the controller 130 so that the water stored in the storage unit 41 is discharged to the outside, or the storage unit. The water stored in the 41 is supplied to the electrolysis unit 42.

The electrolysis driving unit 150 controls the power supply to the electrolysis unit 42 according to the instructions of the control unit 130 to perform electrolysis of water in the electrolysis unit 42.

The pump driving unit 160 transmits driving signals to the first and second pumps 42c and 42d and the third pump 46 according to the instructions of the controller 130 to transmit the first and second pumps 42c and 42d and the third pump. Allow pump 46 to be driven.

The electrolyte supply motor driver 170 controls the driving of the electrolyte supply motor 44c according to the instructions of the controller 130, so that the position of the second hole h2 of the rotating panel 44b is set to the position of the electrolyte container 44a. The electrolyte is supplied to the storage part 41 through the first and second holes h1 and h2 by matching the position of the first hole h1.

The hole detecting unit 180 detects the position of the second hole h2 of the rotating panel 44b so that the first and second holes h1 and h2 are coincident with each other so that the electrolyte can be supplied to the storage unit 41. To the control unit 130.

7 is a flowchart illustrating a washing control of the air conditioner according to the embodiment of the present invention, which will be described with reference to FIGS. 2 to 6.

First, heat exchange of air is performed in the heat exchanger 31 according to the operation of the air conditioner 10, and when water (condensed water) forms in the heat exchanger 31 according to the heat exchange of the heat exchanger 31, Water formed in the group 31 flows to the storage unit 41 and is stored in the storage unit 41. At this time, the first valve 43b of the drain valve is opened to discharge the water stored in the storage 41 to the outside.

Then, when the driving of the air conditioner 10 is stopped and the washing of the heat exchanger 31 is performed, the first valve 43b and the second valve 43d of the drain valve 43 are closed to close the heat exchanger ( The water generated in 31 is stored in the storage unit 41 (301). At this time, the water level detection unit 110 detects the water level of the storage unit 41, and compares the water level of the detected storage unit 41 with a predetermined reference level (302), so that the water level of the storage unit 41 is the reference water level. If it is abnormal, the second valve 43d of the drain valve is opened and water stored in the storage part 41 is supplied to the electrolysis part 42 (303).

Next, power is supplied to the electrolysis unit 42, and the current flowing in the water accommodated in the electrolysis unit 42 is sensed and compared with the preset reference current 304. At this time, if the current flowing in the water contained in the electrolysis unit 42 is equal to or greater than the reference current, it is determined that the water stored in the storage unit 41 is electrolyte dissolved water, and each polarity is different in the pair of electrode plates installed in the electrolysis unit 42. The electrolysis of water contained in the electrolysis unit 42 is performed by applying a power of. The electrolysis unit 42 generates acidic water and alkaline water, which are washing water, by the electrolysis.

The acid water generated during the electrolysis of the electrolysis unit 42 is driven to the first injection unit 45a by driving the first pump 42c. At this time, the first injector 45a sterilizes the heat exchanger 31 by injecting acidic water into the heat exchanger 31. In addition, the alkaline water generated during the electrolysis of the electrolysis unit 42 is driven to the second injection unit 45b by driving the second pump 42d. At this time, the second injection section 45b cleans the heat exchanger 31 by spraying 307 alkaline water onto the heat exchanger 31. At this time, when the power of different polarity is applied to the pair of electrode plates installed in the electrolytic part 42, the polarity is changed at predetermined time intervals, and the acidic and alkaline water are supplied through the first and second injection parts 45a and 45b. Alternately spray.

Then, the acidic water and the alkaline water flowing along the heat exchanger 31 are supplied to the storage unit 41, and the acidic and alkaline water stored in the storage unit 41 are neutralized, and are re-powered by the pumping operation of the third pump 46. It is supplied to the decomposition part 42.

Next, when the washing of the heat exchanger 31 is completed, the drain valve 43 and the third pump 46 are operated to dissolve condensate or electrolyte remaining on the storage part 41, the electrolysis part 42, and each pipe. The water is drained out (308). This is because if the condensed water or the electrolyte solution remains on each pipe for a long time, the condensed water or the electrolyte solution will rot, causing odor.

If the current flowing in the water contained in the electrolysis unit 42 and the reference current are compared 304, if the current flowing in the water contained in the electrolysis unit 42 is less than the reference current, the water stored in the storage unit 41 is stored. By determining that it is condensed water and controlling the driving of the electrolyte supply motor 44c of the electrolyte supply unit 44, the first hole h1 of the electrolyte receiving unit is opened 305 to supply the electrolyte to the storage unit 41 (306).

In this case, the electrolyte is supplied by rotating the electrolyte supply motor 44c so that the position of the first hole h1 of the electrolyte accommodating portion 44a matches the position of the second hole h2 of the rotating panel h2. By opening the first hole h1, the electrolyte e contained in the electrolyte accommodating part 44a is supplied to the storage part 41 through the first and second holes h1 and h2. At this time, when the rotating panel 44b rotates as the electrolyte supply motor 44c rotates, the position of the second hole h2 is sensed through the hole detecting unit 180, and the first and second holes h1 and h2 are detected. If this coincides, the electrolyte e contained in the electrolyte accommodating portion 44a is paused for a suitable time to be supplied to the storage 41, and then the electrolyte supply motor 44c is rotated again to close the first hole h1. Close it.

Here, the electrolyte receiving portion 44a is formed in a spiral shape and is inclined from the center to the outer side, so that one electrolyte disposed in the first hole h1 on the outer side is discharged and is inclined when the first hole h1 is closed. The electrolyte moved along the spiral guide portion a1 is located in the first hole h1 on the outer side.

After supplying the electrolyte to the storage section 41, the electrolyte dissolved water generated in the storage section 41 is supplied to the electrolysis section 42 by supplying the electrolyte, and the electrolyte dissolved in the electrolysis section 42 is dissolved. The current flowing through the water is detected and compared with the reference current to determine whether the electrolyte is added. In this way, it is possible to perform the optimum electrolysis by determining whether to add the electrolyte and by supplying additional electrolyte according to the determination result.

Next, the electrolyte is dissolved in water stored in the storage unit 41 to form electrolyte dissolved water, and the electrolyte dissolved water is supplied to the electrolysis unit 42. The electrolysis unit 42 performs electrolysis of the electrolyte dissolved water to generate washing water such as acidic water and alkaline water, and the generated acidic water and alkaline water are driven by the first and second pumps 42c and 42d. It is moved to the 1st, 2nd injection parts 45a and 45b. The acid and alkaline water supplied to the first and second injection parts 45a and 45b are sprayed 307 to the heat exchanger 31 by the injection operation of the first and second injection parts 45a and 45b. 31), the acidic water and alkaline water flowing along the heat exchanger 31 is supplied to the storage unit 41, the acidic and alkaline water stored in the storage unit 41 is neutralized and the third pump 46 It is supplied to the electrolysis unit 42 again by the pumping operation of.

Next, when the washing of the heat exchanger 31 is completed, the drain valve 43 and the third pump 46 are operated to dissolve condensate or electrolyte remaining on the storage part 41, the electrolysis part 42, and each pipe. The water is drained out (308). This is because if the condensed water or the electrolyte solution remains on each pipe for a long time, the condensed water or the electrolyte solution will rot, causing odor.

The cleaning of the heat exchanger 31 is performed at a predetermined cycle (about two weeks) or at the user's choice.

Here, it is also possible to supply only the acidic water to the injection part 45 and to spray the heat exchanger 31. At this time, the acidic water is an acidic water of pH 3 to pH 4, by spraying the acidic water to the heat exchanger 31 for a predetermined time (about 30 minutes) can remove most of the bacteria inhabiting the heat exchanger (31). .

1 is an external perspective view of an air conditioner according to an embodiment of the present invention.

2 is an internal perspective view of the air conditioner according to the embodiment of the present invention.

3 is a detailed perspective view of the washing apparatus provided in the air conditioner according to the embodiment of the present invention.

4 is an exploded perspective view of the washing apparatus provided in the air conditioner according to the embodiment of the present invention.

5 is a cross-sectional view of the washing apparatus provided in the air conditioner according to the embodiment of the present invention.

6 is a block diagram illustrating the washing control of the air conditioner according to the embodiment of the present invention.

7 is a flowchart illustrating a washing control of the air conditioner according to the embodiment of the present invention.

Description of the Related Art [0002]

11: cabinet 12: front panel

13: inlet 14: blade

15: discharge port 21: blowing fan

22: fan housing 31: heat exchanger

40: washing device 41: storage unit

42: electrolytic part 43: drain valve

44: electrolyte supply unit 44a: electrolyte receiving unit

44b: rotating panel 44c: electrolyte supply motor

44d: cover 45: injection part

50: supply hole

Claims (32)

An electrolyte accommodating part in which an electrolyte is accommodated and a first hole in which the electrolyte is discharged is formed, a rotating panel rotatably installed outside the electrolyte accommodating part to open and close the first hole, and a motor to rotate the rotating panel; An electrolyte supply unit; A storage unit for storing water; An electrolysis unit configured to electrolyze the water by receiving water from the storage unit; And a control unit for determining whether water supplied to the electrolytic unit is electrolyte dissolved water and controlling the motor to control the discharge of the electrolyte according to the determined result. The method of claim 1, The rotating panel has a second hole provided at a position corresponding to the position of the first hole, The control unit, the washing apparatus of the air conditioner to rotate the motor so that the position of the second hole of the rotating panel coincides with the position of the first hole. The method of claim 1, The motor has a rotating shaft, the rotating panel is a washing apparatus of the air conditioner having a shaft insertion portion is inserted into the rotating shaft. The method of claim 1, The electrolyte receiving portion of the cleaning device of the air conditioner further comprises a cover for fixing the fixing projections and sealing the electrolyte receiving portion from the outside. The method of claim 1, The electrolyte is a cleaning device of the air conditioner is a solid electrolyte of a spherical shape. The method of claim 5, The bottom surface of the electrolyte receiving portion is a cleaning device of the air conditioner inclined from the center to the outside. The method of claim 6, The electrolyte receiving unit, the cleaning device of the air conditioner having a guide for guiding the electrolyte to the first hole. The method of claim 7, wherein The guide unit, the cleaning device of the air conditioner formed in a spiral shape. The method of claim 1, Further comprising a hole detecting unit for detecting the position of the second hole of the rotating panel, The control unit, the washing apparatus of the air conditioner for controlling the rotation of the motor in accordance with the detection signal of the second hole transmitted from the hall detection unit. The method of claim 1, The electrolyte supply unit cleaning device of the air conditioner provided above the storage unit. The method of claim 1, Further comprising a current sensing unit for sensing the current flowing in the water accommodated in the electrolysis unit, The control unit is a cleaning device of the air conditioner to determine whether the discharge of the electrolyte by comparing the sensed current with the reference current. The method of claim 1, Sterilization apparatus of the air conditioner further comprises an injection unit for injecting the water electrolyzed in the electrolysis unit to the heat exchanger. The method of claim 1, Further comprising a water level detection unit for detecting the water level of the water stored in the storage unit, The control unit is a washing device of the air conditioner for supplying water to the electrolysis unit when the water level of the storage unit is the reference level when the heat exchanger cleaning. According to claim 1, wherein the water in the storage unit, A sterilizer of an air conditioner, which is water in which condensate generated in a heat exchanger is stored. The method of claim 1, Further comprising a supply hole provided in the cabinet forming the appearance of the air conditioner, Water of the storage unit, the sterilization apparatus of the air conditioner is water supplied by the user through the supply hole. An electrolyte accommodating part in which an electrolyte is accommodated and a first hole in which the electrolyte is discharged is formed, a rotating panel rotatably installed outside the electrolyte accommodating part to open and close the first hole, and a motor to rotate the rotating panel; An electrolyte supply unit; A controller configured to control the motor to discharge the electrolyte when the heat exchanger is cleaned; A storage unit storing water generated when the heat exchanger is driven and generating electrolyte dissolved water when the electrolyte is discharged; An electrolysis unit for electrolyzing the electrolyte dissolved water; And a spray unit for spraying the electrolyzed water into the heat exchanger. The method of claim 16, Further comprising a current sensing unit for sensing the current flowing in the electrolyte dissolved water accommodated in the electrolysis unit, The control unit is a cleaning device of the air conditioner for controlling the further discharge of the electrolyte by comparing the sensed current with the reference current. The method of claim 16, The rotating panel has a second hole provided at a position corresponding to the position of the first hole, The control unit, the washing apparatus of the air conditioner to rotate the motor so that the position of the second hole of the rotating panel coincides with the position of the first hole. The method of claim 18, Further comprising a hole detecting unit for detecting the position of the second hole of the rotating panel, The control unit, the washing apparatus of the air conditioner for controlling the rotation of the motor in accordance with the detection signal of the second hole transmitted from the hall detection unit. The method of claim 16, The motor has a rotating shaft, the rotating panel is a washing apparatus of the air conditioner having a shaft insertion portion is inserted into the rotating shaft. The method of claim 16, The bottom surface of the electrolyte receiving portion is a cleaning device of the air conditioner inclined from the center to the outside. The method of claim 21, The electrolyte receiving unit, the cleaning device of the air conditioner having a spiral guide portion for guiding the electrolyte to the first hole. The method of claim 17, The electrolyte receiving portion has at least one fixing protrusion on the outer circumferential surface, The insertion hole is formed is inserted into which the fixing projection is inserted, the cleaning device of the air conditioner further comprises a cover for fixing the electrolyte receiving portion and sealed from the outside. Supply the water stored in the storage to the electrolysis unit, It is determined whether the water supplied to the electrolysis part is electrolyte dissolved water, Rotate the rotating panel by controlling the motor according to the determined result, And controlling the discharge of the electrolyte to the storage unit by controlling opening and closing of the first hole of the electrolyte receiving unit according to the rotation of the rotating panel. The method of claim 24, When the water supplied from the reservoir is electrolyte dissolved water, the electrolyte dissolved water is electrolyzed to generate washing water. The washing control method of the air conditioner further comprises the step of washing the heat exchanger by spraying the washing water to the heat exchanger. The method of claim 25, The washing control method of the air conditioner further comprises discharging the washing water to the outside when the washing of the heat exchanger is completed. The method of claim 24, wherein the determining whether the electrolyte is dissolved water, The washing control method of the air conditioner for sensing the current flowing in the water accommodated in the electrolysis unit, and comparing the detected current and the reference current. The method of claim 24, wherein the supply of water to the electrolysis unit, If the water level of the storage unit is a reference level, the washing control method of the air conditioner further comprising supplying the water to the electrolysis unit. The method of claim 24, Detect the current flowing in the water accommodated in the electrolysis unit and compare with the reference current, And controlling further discharging of the electrolyte according to the compared result. The water generated in the heat exchanger is stored in the storage unit, When the washing of the heat exchanger to control the motor to rotate the rotating panel, Opening the first hole of the electrolyte receiving portion in accordance with the rotation of the rotating panel, Discharging the electrolyte to the storage through the opened first hole, When the electrolyte is dissolved in the water of the storage part and the electrolyte dissolved water, the electrolyte dissolved water is supplied to the electrolytic part, Washing and controlling the air conditioner by electrolytically dissolving the electrolyte dissolved water to the heat exchanger. 31. The method of claim 30, Sensing the current flowing in the electrolyte dissolved water supplied to the electrolysis unit, And controlling the additional discharge of the electrolyte when the sensed current is less than the reference current. The method of claim 30, wherein opening the first hole, And a position of the first hole of the electrolyte accommodating portion and a position of the second hole of the rotary panel.

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