KR20220029476A - Air Conditioner with Evaporator Cleaning function - Google Patents

Abstract

The present invention relates to an air conditioner with a function of cleaning an evaporator of an indoor unit and an operating method, wherein the air conditioner can wash away and discharge contaminants, attached on the surface of an evaporator coil, together with water by rapidly freezing, unfreezing and drying the evaporator coil during an indoor cooling operation, and further can sterilize the evaporator at high temperature after removing the contaminants. The air conditioner according to the present invention includes a compressor (10), a condenser (20) of an outdoor unit, an electronic control expansion valve (30), an evaporator (40) of an indoor unit, an outdoor unit fan (22) and an indoor unit fan (42). In addition, the air conditioner further includes: an input unit (110) for allowing a user to input a selection of a washing command, a cooling operation/stop command and an operation mode with respect to the evaporator (40); and a control unit (100) programmed to perform an evaporator freezing operation for lowering the opening rate of the electronic control expansion valve (30) to a rapid freezing mode reference in order to rapidly lower the surface temperature of the evaporator (40) to 0 ℃ or less, while being operated in a cooling operation mode or after first an operation in a cooling operation mode starts and a set time has passed, if receiving an evaporator washing command from the input unit (110) or a stored evaporator washing reservation time has arrived, perform an evaporator unfreezing operation for melting ice on the surface of the evaporator (40) by completely opening the opening rate of the electronic control expansion valve (30) after freezing the surface of the evaporator (40), and perform an evaporator drying operation for drying the surface of the evaporator (40) by driving the indoor unit fan (42) after unfreezing.

Description

An air conditioner having an evaporator cleaning function of an indoor unit and an operation method {Air Conditioner with Evaporator Cleaning function}

The present invention relates to washing an evaporator coil provided in an indoor unit of an air conditioner, and more particularly, by rapidly freezing the evaporator coil during an indoor cooling operation and then thawing and drying the contaminants attached to the surface of the evaporator coil The present invention relates to an air conditioner having an evaporator cleaning function of an indoor unit that is washed down with water and discharged, and further, the evaporator can be sterilized at a high temperature after removal of pollutants, and an operating method.

In general, an air conditioner is a device for maintaining a comfortable temperature indoors by performing a series of refrigerant cycles of compressing → condensing → expanding → evaporating a refrigerant to cool indoor air.

As the air conditioner, a separate type air conditioner in which a heat dissipating unit having a condenser and a heat absorbing unit having an evaporator are separately installed is generally used. At this time, since the heat dissipating unit is installed outdoors, it is usually referred to as an 'outdoor unit', and the heat absorption unit is referred to as an 'indoor unit' because it is installed in an air conditioning space, that is, indoors.

Referring to FIG. 1 , the outdoor unit 1 includes a compressor 10 for compressing a refrigerant, a condenser 20 for cooling the compressed high-temperature and high-pressure refrigerant by external air and condensing it into a liquid, and a condenser for blowing outdoor air to the condenser It includes an outdoor unit fan (blowing fan) 22 , and an expansion valve 30 , which expands the refrigerant condensed in the condenser 20 into a low-temperature and low-pressure refrigerant and sends it to the evaporator 40 of the indoor unit 2 .

The indoor unit 2 includes an evaporator 40 that absorbs ambient heat by evaporating the low-temperature and low-pressure refrigerant flowing in from the expansion valve 30, and sucks indoor air and passes it through the evaporator 40 to enter the room. An indoor unit fan (blowing fan) 42 for blowing air is provided. The indoor unit 2 and the outdoor unit 1 are connected by a refrigerant pipe 4 .

Here, the expansion valve 30 depressurizes the high-temperature and high-pressure liquid refrigerant condensed and liquefied in the condenser 20 to a pressure capable of causing evaporation by a throttling action in order to absorb sufficient heat in the evaporator 40 , It plays a role in regulating the supply.

When the cooling operation is performed, a low-temperature and low-pressure refrigerant flows into the evaporator 40 and evaporates to lower the surface temperature of the evaporator coil. When the fan 42 is driven, indoor air flows in through the inlet of the indoor unit 2 and then passes between the coils of the evaporator 20 to lower the temperature, and is then supplied to the room through the outlet.

As described above, during the cooling operation, the surface temperature of the evaporator 40 (the surface temperature of the evaporator coil) is lower than the dew point temperature of the room air, so that water vapor in the air condenses on the surface of the evaporator 40 to form water. (Dew, moisture) is formed, and the dew formed in this way remains unremoved even after the air conditioner stops working.

As such, the moisture remaining on the surface of the evaporator 40 even after the operation of the air conditioner is stopped is the main cause of attachment and propagation of various kinds of dust, germs, and mold. If it does, it will enter the room and adversely affect human hygiene as well as bad odors.

In general, the air intake part of the indoor unit is equipped with a filter to filter out dust, but since fine dust not only can pass through the filter, but also the dust enters through the minute gap of the door flap of the outlet, it is perfect It is difficult to block

In order to solve the above problem, according to a conventional example, a technique of removing moisture remaining on the surface by drying the surface of the evaporator by operating an indoor fan for a certain period of time after operating the air conditioner has been proposed (eg, ; see Patent Document 1, etc.). However, according to this method, as the surface of the evaporator is dried and the foreign substances contained in the moisture are attached to the surface of the evaporator as it is, the growth of mold can be reduced, but the foreign substances cannot be completely removed from the surface of the evaporator.

On the other hand, unlike the cooling-only air conditioner shown in FIG. 1, a cooling cycle that cools indoor air in summer is operated, and a heating cycle that heats indoor air in winter (refrigerant is circulated in the reverse direction of the cooling cycle by a 4-way valve) A type of air conditioner that can be operated with Sikkim) is being used.

When such an air conditioner for heating and cooling performs a heating cycle, the condenser (outdoor heat exchanger) of the outdoor unit acts as an evaporator. In particular, frost forms on the surface of the evaporator due to the low outdoor temperature in winter, In order to defrost the outdoor unit, the heating operation is stopped and the operation is reversed (indoor cooling cycle) to remove the frost adhering to the surface of the outdoor heat exchanger. A system (eg, refer to Patent Document 2, etc.) has been proposed, but a proper solution for removing contaminants from the surface of the evaporator of the indoor unit during indoor cooling operation in summer has not been proposed.

Korean Patent Publication No. 10-2005-0032667 (April 2005) Republic of Korea Patent Publication No. 10-2060363 (2005.04.08)

The present invention has been proposed to solve the above problems, and an object of the present invention is to make it possible to easily wash contaminants attached to the surface of an evaporator.

Another object of the present invention is to make it possible to easily wash contaminants adhering to the surface of an evaporator during an indoor cooling operation even in a cooling-only air conditioner that does not perform the reverse cycle of the cooling cycle or cannot perform the reverse cycle. there is.

In addition, in the case of an air conditioner for heating and cooling that can perform the reverse cycle, the purpose is to further sterilize the evaporator at a high temperature after removing contaminants.

The object of the present invention as described above is to perform a cycle of rapidly freezing the evaporator coil during indoor cooling operation and then thaw and dry the contaminants adhering to the surface of the evaporator coil to be washed away with water and discharged. This is achieved by providing an air conditioner having an evaporator cleaning function of an indoor unit capable of performing high-temperature sterilization of an evaporator coil, and an operating method.

Specifically, the air conditioner having an evaporator cleaning function of an indoor unit according to the present invention includes a compressor (10) that compresses a refrigerant, and a condenser of an outdoor unit (1) that cools the compressed high-temperature and high-pressure refrigerant by external air and condenses it into a liquid. (20), an electronically controlled expansion valve 30 that expands the refrigerant condensed in the condenser 20 into a low-temperature and low-pressure refrigerant, and evaporates the low-temperature and low-pressure refrigerant exiting the electronically controlled expansion valve 30 to reduce surrounding heat. A refrigerant circuit including an evaporator 40 of the indoor unit 2 that absorbs and cools air, an outdoor unit fan 22 that blows outside air to the condenser 20, and air cooled through the evaporator 40 an indoor unit fan 42 for blowing air into the room, and an input unit 110 for a user to input a washing command for the evaporator 40 of the indoor unit 2, a cooling operation/stop command, and selection of an operation mode; When the evaporator cleaning command is received from the input unit 110 or the stored evaporator cleaning reservation time arrives, the electronically controlled expansion valve is operated during operation in the cooling operation mode or in the cooling operation mode first, and after a set time elapses, the electronically controlled expansion valve An evaporator freezing operation is performed to lower the opening degree of (30) based on a quick freezing mode for rapidly lowering the surface temperature of the evaporator 40 to 0 ° C. or less, and after the surface of the evaporator 40 is frozen, the electronic control The evaporator thawing operation is performed to melt the ice on the surface of the evaporator 40 by completely opening the expansion valve 30, and after thawing, the indoor unit fan 42 is operated to dry the surface of the evaporator 40. Evaporator drying The control unit 100 is programmed to perform a driving operation.

In the air conditioner according to the present invention, it is installed on the refrigerant circuit on the outlet side of the compressor (10) so that the refrigerant exiting the compressor (10) flows to the condenser (20) which is an outdoor unit in a cooling operation (normal cycle), In the heating operation (reverse cycle), the reverse cycle may be performed by further including a four-way valve 60 capable of switching the flow direction of the refrigerant to flow to the evaporator 40 of the indoor unit.

In the air conditioner according to the present invention, the evaporator installed between the evaporator 40 of the indoor unit 2 and the indoor unit fan 42 to measure the humidity of the evaporator 40 and provide it to the control unit 100 . The humidity sensor 50, the evaporator surface temperature sensor 56 installed in the indoor unit 2 to measure the temperature of the surface of the evaporator 40 and provide it to the control unit 100, and the outside air temperature In order to provide to the control unit 100, an outdoor temperature sensor 58 installed in the outdoor unit 1, and installed in the indoor unit 2 to measure the indoor temperature and provide it to the control unit 100 An indoor temperature sensor 54 may be further provided.

In the air conditioner according to the present invention, the controller 100 measures the outdoor air temperature of the outdoor unit 1 before starting the freezing operation of the evaporator, and when the measured outdoor air temperature exceeds a set temperature, the compressor ( 10) and the driving intensity of the outdoor unit fan 22 may be set to be upwardly adjusted.

In the air conditioner according to the present invention, the controller 100 measures the surface temperature of the evaporator 40 after a set time has elapsed after the start of the freezing operation of the evaporator, and the surface temperature of the evaporator 40 is rapidly frozen. When the temperature is higher than the set temperature for , it can be set to lower the opening degree of the electronically controlled expansion valve 30 by one step until the temperature standard for rapid freezing is satisfied.

In the air conditioner according to the present invention, the controller 100 may set to stop the operation of the compressor 10 during the evaporator thawing operation.

In the air conditioner according to the present invention, when a set time elapses after the start of the drying operation of the evaporator, the control unit 100 measures the humidity of the surface of the evaporator 40, and drying the surface humidity of the evaporator 40 is set. When the level is not satisfied, it may be set to extend the operating time of the indoor fan 42 .

In the air conditioner according to the present invention, the controller 100 may set the evaporator freezing operation, the evaporator thawing operation, and the evaporator drying operation to be repeatedly performed a plurality of times.

In the air conditioner operation method according to the present invention, when the evaporator cleaning reservation time stored in the control unit 100 arrives (step S10) or the user directly manipulates the input unit 110 during the cooling operation to input the evaporator cleaning command (Step S20), the process of checking whether the air conditioner is currently operating in the cooling operation mode (Step S30); If the cooling operation is not in progress in the above process (step S3O), the process of executing the cooling operation mode (step S40); The process of switching to the evaporator washing operation mode during the cooling operation in the process (step S3O) or when a set time elapses after performing the cooling operation mode in the process (step S40) (step S50); Evaporator freezing that freezes on the surface of the evaporator 40 of the indoor unit by adjusting the opening degree of the electronically controlled expansion valve 30 to be reduced based on the quick freezing mode for rapidly lowering the surface temperature of the evaporator 40 of the indoor unit to 0° C. or less the process of driving (step S100); After the evaporator freezing operation (step S100) is performed for a set time (step S110), the opening degree of the electronically controlled expansion valve 30 is completely opened to melt the ice on the surface of the evaporator 40 of the indoor unit. process (step S120); After the thawing operation (step S120) of the evaporator 40 of the indoor unit is performed for a set time (step S130), the driving strength of the indoor unit fan 42 is increased to dry the water on the surface of the evaporator 40 of the indoor unit. a process of performing a drying operation (step S140); And after performing the evaporator drying operation (step S140) for a set time (step S150), the process of terminating the evaporator washing operation (step S160); is made including

In the air conditioner operation method according to the present invention, after the evaporator cleaning operation is terminated (step S160), when the evaporator cleaning operation is performed by a user's command input during the cooling operation, the operation is switched back to the normal cooling operation (step S160). S170), the operation of the air conditioner is terminated according to the user's operation end command (step S180) (step S190), and when the operation of the air conditioner is stopped and the evaporator cleaning operation is performed due to the arrival of the reserved time It is preferable to further perform the process (step S190) of immediately terminating the operation of the air conditioner (“reservation execution” in step S162).

In the air conditioner operation method according to the present invention, before starting the evaporator freezing operation (step S100), when the outdoor temperature is received from the outdoor temperature sensor 58 (step S52), and the temperature of the outdoor air is higher than the set temperature , it is preferable to increase the rotational speeds of the compressor 10 and the outdoor unit fan 22 (step S54).

In the air conditioner operation method according to the present invention, after a set time has elapsed after the start of the freezing operation of the evaporator (step S110), the surface temperature of the evaporator 40 is measured (step S112), and the temperature of the evaporator 40 of the indoor unit is measured. When the surface temperature is higher than the set temperature for quick freezing (No in step S113), the opening degree of the electronically controlled expansion valve 30 is lowered by one step until the temperature standard for quick freezing is met and maintained for the set time It is preferable to repeat the process (step S114).

In the air conditioner operation method according to the present invention, it is preferable to stop the indoor unit fan 42 or lower it to a minimum speed when the evaporator freezing operation (step S100) is performed.

In the method of operating the air conditioner according to the present invention, it is preferable to stop the operation of the compressor 10 when the evaporator thawing operation (step S120 ) is performed.

In the air conditioner operation method according to the present invention, after the above process (step S150), the humidity of the air adjacent to the surface of the evaporator 40 or the evaporator 40 is received from the evaporator humidity sensor 50 (step S152), and the humidity does not meet the preset reference value (No in step S154), extending the operation time (evaporator drying operation time) of the indoor unit fan 42 until the humidity meets the preset reference value desirable.

In the air conditioner operating method according to the present invention, after the evaporator cleaning operation is finished (step S160), the evaporator high temperature sterilization is performed by maintaining the temperature of the evaporator 40 of the indoor unit at a high temperature to sterilize the surface of the evaporator 40 . the process of switching to driving (step S200); Entering the high-temperature sterilization operation, the four-way valve 60 is switched to a reverse cycle so that the refrigerant discharged from the compressor 10 flows into the evaporator 40 of the indoor unit, so that the evaporator 40 of the indoor unit plays the role of a condenser for heating the process of driving (step S210); a process of continuously performing the heating operation for a set time while the surface temperature Ta of the evaporator 40 of the indoor unit is equal to or higher than the set temperature for sterilization (step S260); And the process of terminating the high-temperature sterilization operation after the lapse of the set time (step S270); can be further performed.

In the method of operating the air conditioner according to the present invention, when the heating operation (step S210) is performed, the indoor unit fan 42 is stopped or the driving intensity is reduced to a minimum speed, and the door flap is closed or kept in a minimum open state It is preferable to do so.

In the air conditioner operating method according to the present invention, after starting the heating operation (step S210), the surface temperature Ta of the evaporator 40 of the indoor unit is measured (step S230), and the surface temperature Ta It is determined whether the set temperature for sterilization is satisfied (step S240), and the process (S250) of increasing the compressive strength of the compressor 10 one step at a time until the surface temperature Ta is equal to or higher than the set temperature for sterilization. it is preferable

In the air conditioner operation method according to the present invention, after the high temperature sterilization operation of the evaporator is terminated (step S270), when the evaporator cleaning operation is performed by the user's command input during the cooling operation, the operation is switched back to the normal cooling operation ( In step S170), the operation of the air conditioner is terminated according to the user's operation end command (step S180) (step S190), and the evaporator washing operation is performed by the arrival of the reserved time in a state in which the operation of the air conditioner is stopped. In this case (“reservation execution” in step S162), the operation of the air conditioner may be immediately terminated.

According to the air conditioner having the evaporator cleaning function of the indoor unit according to the present invention, contaminants adhering to the surface of the evaporator can be easily washed by performing the evaporator freezing → thawing → drying cycle.

In addition, contaminants adhering to the surface of the evaporator can be easily cleaned during the indoor cooling operation even in the case of an air conditioner exclusively for cooling without performing the reverse cycle of the cooling cycle or incapable of performing the reverse cycle.

In addition, in the air conditioner for heating and cooling that can perform the reverse cycle, by performing the cycle of freezing → thawing → drying → high temperature sterilization, it is possible to further sterilize the indoor unit (evaporator) at a high temperature after removing contaminants, thereby improving indoor hygiene. can be improved

1 is a diagram showing the configuration of an air conditioner according to a first embodiment of the present invention.
2 is a block diagram showing the configuration of a control unit and control elements of the present invention.
3 is a flowchart illustrating an evaporator cleaning control flow according to the present invention.
FIG. 4 is a part of a flowchart illustrating a control flow of the evaporator washing operation mode of FIG. 3 .
5 is a flowchart illustrating a control flow following the process of FIG. 4 .
6 is a diagram illustrating a configuration of an air conditioner according to a second embodiment of the present invention.
7 is a block diagram showing the configuration of a control unit and control elements according to a second embodiment of the present invention.
8 is a part of a flowchart illustrating a control flow for additionally performing high-temperature sterilization in the air conditioner according to the second embodiment of the present invention.
9 is a flowchart illustrating a control flow following the process of FIG. 8 .

Hereinafter, specific embodiments of an air conditioner having an evaporator cleaning function of an indoor unit and a cleaning method of an indoor unit according to the present invention will be described with reference to the accompanying drawings.

<First embodiment>

FIG. 1 is a diagram showing the configuration of an air conditioner of the present invention, and FIG. 2 is a block diagram showing the configuration of a control unit and control elements of the present invention. Although FIG. 1 shows and describes a cooling-only air conditioner having only a cooling operation function, the same configuration can be applied to a cooling/heating air conditioner ( FIGS. 6 to 9 ) that can perform a reverse cycle by a 4-way valve. , Hereinafter, the air conditioner exclusively for cooling and the air conditioner for both heating and cooling will be described in an integrated manner without distinguishing between them.

1 and 2, the air conditioner of the present invention includes a compressor 10 for compressing a refrigerant, and a condenser (outdoor heat exchanger) 20 for cooling the compressed high-temperature and high-pressure refrigerant by external air and condensing it into a liquid. ), an electronically controlled expansion valve 30 that expands the refrigerant condensed in the condenser 20 into a low-temperature and low-pressure refrigerant, and evaporates the low-temperature and low-pressure refrigerant from the electronically controlled expansion valve 30 to absorb surrounding heat. It has a refrigerant circuit comprising an evaporator (indoor heat exchanger) 40 for cooling the air.

In addition, an outdoor unit fan 22 for blowing outside air to the condenser 20 and an indoor unit fan 42 for blowing air cooled through the evaporator 40 into the room are provided.

Here, the condenser 20 is installed on the outdoor unit 1 side, and the evaporator 40 is installed on the indoor unit 2 side. The compressor 10 and the electronically controlled expansion valve 30 may be installed in the outdoor unit 1 .

In addition, the outdoor unit 1 is provided with an outdoor unit fan 22 that blows outside air to the condenser 20, and the indoor unit 2 has an indoor unit fan 42 that blows the cooled air through the evaporator 40 into the room. ) is provided.

In addition, service valves V1 and V2 for blocking the refrigerant pipe 4 during maintenance may be provided in the refrigerant pipe 4 .

In addition, the air conditioner of the present invention may include an evaporator humidity sensor 50, an indoor humidity sensor 52, an indoor temperature sensor 54, and an evaporator surface temperature sensor 56 in the indoor unit 2, and the indoor unit ( 2) may include an outdoor temperature sensor 58 .

In addition, while performing an overall control operation of the air conditioner, detection values are received from the respective sensors 50 , 52 , 54 , 56 and 58 , and the compressor 10 , the electronically controlled expansion valve 30 , and the outdoor unit and a control unit 100 for controlling the fan 22 and the indoor unit fan 42 .

In addition, the input unit 110 is provided for the user to input a washing command for the evaporator 40 of the indoor unit 2, various cooling operation, stop, selection of an operation mode, and the like. The input unit 110 may be a remote controller, and may include a control panel installed in the case of the indoor unit 2 and a remote controller.

The evaporator humidity sensor 50 measures the humidity of the evaporator 40 and provides it to the control unit 100 . The evaporator humidity sensor 50 may be installed between the evaporator 40 in the indoor unit 2 and the indoor unit fan 42 .

The indoor humidity sensor 52 and the indoor temperature sensor 54 measure indoor humidity and temperature and provide the measured indoor humidity and temperature to the controller 100 . The indoor humidity sensor 52 and the indoor temperature sensor 54 may be installed in the case of the indoor unit 2 in communication with the room.

The evaporator surface temperature sensor 56 measures the surface temperature of the evaporator 40 and provides it to the control unit 100 . The evaporator surface temperature sensor 56 may be installed close to the surface of the evaporator 40 in the case of the indoor unit 2 .

The outdoor air temperature sensor 58 measures the outdoor air temperature on the side of the outdoor unit 1 and provides it to the controller 100 . The outdoor air temperature sensor 58 is installed on one side of the outdoor unit 1 to communicate with the outdoor air.

Next, with reference to FIGS. 3 to 5 , the control flow of washing the evaporator and the control function and operation process of the control unit 100 according to the present invention will be described. Reference numerals for components refer to FIGS. 1 to 2 .

3 is a flowchart illustrating an evaporator cleaning control flow, and FIGS. 4 and 5 show a control flow in an evaporator cleaning operation mode.

First, referring to FIG. 3 , the evaporator washing reservation time input by the user in advance and stored in the control unit 100 arrives (step S10), or the user directly manipulates the input unit 110 during the cooling operation to command the evaporator washing is input (step S20), the control unit 100 checks whether the operation is in the cooling operation mode (step S30), and if not in the cooling operation (eg, the air conditioner is stopped while the operation of the air conditioner is stopped, the reservation time for washing the evaporator is ), the cooling operation is performed by first executing the cooling operation mode.

Next, the control unit 100 executes (switches) the evaporator cleaning operation mode when a set time elapses after performing the cooling operation (step S50). While the operation of the air conditioner is stopped, the cooling operation is performed before the cleaning operation as the evaporator cleaning reservation time arrives to cause dew to form on the surface of the evaporator 40, while stabilizing the refrigeration cycle This is to receive and understand indoor and outdoor environmental conditions from various sensors.

Next, a detailed process of the evaporator cleaning operation mode (step S50) will be described with reference to FIGS. 4 and 5 .

In the evaporator washing operation mode (step S50), the control unit 100 performs the evaporator freezing operation (step S100).

In the evaporator freezing operation, the control unit 100 adjusts the opening degree of the electronically controlled expansion valve 30 to be reduced based on the rapid freezing mode for rapidly lowering the surface temperature of the evaporator 40 to 0° C. or less. That is, the opening degree is reduced to a temperature at which dew formed on the surface of the evaporator 40 and surrounding moisture can be frozen. Then, the high-temperature and high-pressure refrigerant compressed in the compressor 10 passes through the very narrow passage of the electronically controlled expansion valve 30, and the low-temperature and low-pressure refrigerant, which is lower than that during the cooling operation, is introduced into the evaporator 40 in a small amount. The surface temperature of the evaporator 40 is lowered to a sub-zero temperature lower than the temperature of the cooling operation (eg, 5 to 10° C.), and accordingly, it can be rapidly frozen. The range of the opening degree of the expansion valve 30 is a range in which the temperature of the evaporator 40 can be maintained below zero while the freezing operation of the evaporator 40 is continued.

Meanwhile, before starting the freezing operation of the evaporator (step S100 ), the driving strength of the compressor 10 and the outdoor fan 22 may be controlled.

For example, the control unit 100 receives the outdoor temperature input from the outdoor air temperature sensor 58 (step S52), and when the outdoor air temperature is higher than a set temperature, the compressor 10 and the outdoor unit fan 22 rotate By increasing the speed high (adjusting the driving strength upward) to increase the temperature and pressure of the refrigerant discharged from the compressor 10, heat exchange in the condenser 20 is made well (condensation is made well) of the evaporator 40 Make it easy to freeze.

When performing the evaporator freezing operation, the controller 100 may adjust the driving strength of the indoor unit fan 42 and the door flaps (not shown) of the indoor unit 2 (step S102).

For example, the indoor unit fan 42 may be controlled to stop or rotate at a minimum speed. In addition, the door flap for controlling the wind direction can be closed or opened. Even if the indoor unit fan 42 stops or rotates at a minimum speed, there is no problem in freezing the evaporator even if the door flap is closed or opened. As it is prevented from being released into the air, the comfort of the room does not deteriorate.

When the evaporator freezing operation (step S100) is performed for a set time (step S110), the controller 100 performs the evaporator thawing operation (step S120).

Upon entering the evaporator thawing operation (step S120 ), the control unit 100 controls to completely open the opening degree of the electronically controlled expansion valve 30 . When the opening degree of the electronically controlled expansion valve 30 is maximally opened, a relatively high temperature and high pressure refrigerant (that is, a refrigerant with less expansion) flows into the evaporator 40, so that the temperature of the evaporator 40 increases (evaporation is well It is not made), and accordingly, it is possible to thaw the ice on the surface of the evaporator 40 . At this time, contaminants such as dust frozen together with water (dew) on the surface of the evaporator 40 are washed down as the ice melts. The water washed down in this way is received by a drip tray installed below the evaporator 40 of the indoor unit 2 and discharged to the outside.

In addition, in the evaporator thawing operation (step S120 ), the control unit 100 may stop the operation of the compressor 10 so that the thawing may be performed more smoothly.

Meanwhile, before performing the evaporator thawing operation (step S120 ), it is preferable to measure the surface temperature of the evaporator 40 to clearly confirm whether ice is formed on the surface of the evaporator 40 . In this case, the control unit 100 receives the surface temperature value of the evaporator 40 from the evaporator surface temperature sensor 56 (step S112), and if the surface temperature of the evaporator 40 is the temperature at which ice cannot be frozen If it is, the opening degree of the electronically controlled expansion valve 30 is further reduced by one step and maintained for a set time (step S114). In this way, after the surface of the evaporator 40 is reliably frozen, the evaporator thawing operation is performed.

After the evaporator thawing operation (step S120) is performed for a set time (step S130), the controller 100 performs the evaporator drying operation operation (step S140).

On the other hand, before performing the evaporator drying operation (step S140), after a set time elapses after the start of the evaporator freezing operation (step S110), the surface temperature of the evaporator 40 is measured (step S112), and the evaporator of the indoor unit ( 40), it is determined whether the surface temperature meets the set temperature for rapid freezing (step S113).

When the surface temperature of the evaporator 40 of the indoor unit is higher than the set temperature (No in step S113), the opening degree of the electronically controlled expansion valve 30 is lowered by one step until the temperature standard for rapid freezing is met. The process of maintaining for a period of time (step S114) is repeatedly performed.

Next, referring to FIG. 5 , in the evaporator drying operation (step S140 ), the controller 100 operates the indoor fan 42 to dry the surface of the evaporator 40 .

The evaporator drying operation is performed until the evaporator 40 is sufficiently or completely dried. To this end, the controller 100 receives the humidity of the air adjacent to the evaporator 40 surface or the evaporator 40 from the evaporator humidity sensor 50 after the evaporator drying operation is maintained for a set time (step S150). (Step S152), if the humidity does not meet the preset reference value (No in Step S154), the operating time of the indoor unit fan 42 (evaporator dry operation) until the humidity meets the preset reference value time) is extended.

When the evaporator drying operation is ended in this way, the control unit 100 ends all the evaporator cleaning operations (step S160).

The control unit 100 may be set to repeat this series of evaporator cleaning operation cycles (steps S52 to S160) several times (eg, 2-3 times).

When all of the evaporator cleaning operation is finished (step S160), if the evaporator cleaning operation is performed by the user's command input during the cooling operation, it is switched back to the normal cooling operation (step S170), and according to the user's operation end command ( Step S180) The operation of the air conditioner is ended (step S190).

If the evaporator cleaning operation is performed due to the arrival of the reserved time while the operation of the air conditioner is stopped instead of during the cooling operation (“reservation execution” in step S162), the control unit 100 may immediately The operation of the conditioner is finished (step S190).

As described above, according to the present invention, contaminants adhering to the surface of the evaporator can be easily washed by performing a cycle of freezing → thawing → drying of the evaporator.

In addition, contaminants adhering to the surface of the evaporator can be easily cleaned during the indoor cooling operation even in the case of an air conditioner exclusively for cooling without performing the reverse cycle of the cooling cycle or incapable of performing the reverse cycle.

<Second embodiment>

In the second embodiment, in the air conditioner for heating and cooling, which can perform the reverse cycle of the cooling cycle, the contaminants attached to the surface of the evaporator are frozen → thawed → dried during the indoor cooling operation without performing the reverse cycle of the cooling cycle. This is an embodiment in which the surface of the evaporator, which is an indoor unit, can be additionally sterilized by performing a cycle and washing, while not stopping the freeze washing, and then performing a reverse cycle.

6 to 7 show the configuration of an air conditioner according to a second embodiment of the present invention. FIG. 6 is a circuit diagram, and FIG. 7 is a block diagram showing the configuration of the control unit and control elements. there is.

6 to 7 , the air conditioner according to the second embodiment has a configuration that further includes a four-way valve 60 compared to the air conditioner according to the first embodiment.

That is, the refrigerant circuit between the condenser 20 which is the outdoor unit and the evaporator 40 of the indoor unit further includes a four-way valve 60 capable of switching the flow direction of the refrigerant exiting the compressor 10 .

In the cooling operation (normal cycle), the four-way valve 60 is switched to send the refrigerant discharged from the compressor 10 to the condenser 20 of the outdoor unit 1 . At this time, the refrigerant exiting the evaporator 40 of the indoor unit 1 enters the compressor 10 through the four-way valve 60 .

In the heating operation (reverse cycle), the four-way valve 60 is switched to send the refrigerant discharged from the compressor 10 to the evaporator 40 of the indoor unit 2 . At this time, the evaporator 40 of the indoor unit 2 functions as a condenser. Also, the condenser 20 of the outdoor unit 1 functions as an evaporator, and the refrigerant exiting the condenser 20 of the outdoor unit 1 enters the compressor 10 through the four-way valve 60 .

Since the rest of the configuration is the same as that of the first embodiment described with reference to FIGS. 1 and 2 , a redundant description will be omitted.

Next, FIGS. 8 to 9 are flowcharts illustrating a control flow for additionally performing high-temperature sterilization in the air conditioner according to the second embodiment of the present invention.

8 to S160 is the same as the control process according to the first embodiment. That is, the control process from step S10 to step S160 described with reference to FIGS. 3 to 5 is the same.

The control process from step S10 to step S160 described with reference to FIGS. 3 to 5 is briefly summarized as follows.

That is, when the evaporator cleaning reservation time stored in the control unit 100 arrives (step S10) or when the user directly manipulates the input unit 110 to input an evaporator cleaning command during the cooling operation (step S20), the air conditioner is currently The process of checking whether the operation is in the cooling operation mode (step S30); If the cooling operation is not in progress in the above process (step S3O), the process of executing the cooling operation mode (step S40); The process of switching to the evaporator washing operation mode during the cooling operation in the process (step S3O) or when a set time elapses after performing the cooling operation mode in the process (step S40) (step S50); Evaporator freezing that freezes on the surface of the evaporator 40 of the indoor unit by adjusting the opening degree of the electronically controlled expansion valve 30 to be reduced based on the quick freezing mode for rapidly lowering the surface temperature of the evaporator 40 of the indoor unit to 0° C. or less the process of driving (step S100); are performed in turn.

Here, before starting the evaporator freezing operation (step S100), the outdoor temperature is received from the outdoor temperature sensor 58 (step S52), and when the temperature of the outdoor air is higher than the set temperature, the compressor 10 and the outdoor unit fan ( 22) is adjusted upward (step S54).

Then, after a set time has elapsed after the start of the freezing operation of the evaporator (step S110), the surface temperature of the evaporator 40 is measured (step S112), and the surface temperature of the evaporator 40 of the indoor unit is set at the set temperature for rapid freezing If it is higher (No in step S113), the process of lowering the opening degree of the electronically controlled expansion valve 30 by one step and maintaining it for a set time until the temperature standard for rapid freezing is met (step S114) is repeated. .

When performing the evaporator freezing operation (step S100), it is preferable to stop the indoor unit fan 42 or lower it to a minimum speed.

Then, after the evaporator freezing operation (step S100) is performed for a set time (step S110), the opening degree of the electronically controlled expansion valve 30 is fully opened to melt the ice on the surface of the evaporator 40 of the indoor unit. performed (step S120).

When the evaporator thawing operation (step S120) is performed, the operation of the compressor 10 may be stopped.

In addition, after the thawing operation (step S120) of the evaporator 40 of the indoor unit is performed for a set time (step S130), the driving strength of the indoor unit fan 42 is increased to dry the water on the surface of the evaporator 40 of the indoor unit. The evaporator drying operation is performed (step S140).

After the evaporator drying operation (step S140) is performed for a set time (step S150), the evaporator washing operation is terminated (step S160).

After the above process (step S150), the humidity of the air adjacent to the surface of the evaporator 40 or the evaporator 40 is received from the evaporator humidity sensor 50 (step S152), and if the humidity does not meet the preset reference value ( 'No') in step S154), the operation time (evaporator drying operation time) of the indoor unit fan 42 is extended until the humidity meets a preset reference value.

In the air conditioner operation method according to the second embodiment of the present invention, the contaminants attached to the surface of the evaporator are frozen → thawed → drying cycle during indoor cooling operation without performing the reverse cycle of the cooling cycle as in the first embodiment. On the other hand, it does not stop with the freeze washing, and then a reverse cycle is performed to further sterilize the surface of the evaporator, which is an indoor unit.

That is, in FIG. 8, after the evaporator washing operation is finished (step S160), the temperature of the evaporator 40 of the indoor unit is maintained at a high temperature to perform sterilization on the surface of the evaporator 40. Switch to the high temperature evaporator sterilization operation ( step S200).

Entering the high-temperature sterilization operation, the four-way valve 60 is switched to a reverse cycle so that the refrigerant discharged from the compressor 10 flows into the evaporator 40 of the indoor unit, so that the evaporator 40 of the indoor unit plays the role of a condenser for heating Driving is performed (step S210).

When performing the heating operation (step S210), it is preferable to stop the indoor unit fan 42 or lower the driving intensity to a minimum speed and close the door flap.

For example, the indoor unit fan 42 may be controlled to stop or rotate at a minimum speed. In addition, the door flap for controlling the wind direction is preferably closed or kept at a minimum open state. When the indoor unit fan 42 is stopped or the door flap is closed, the air heated by heat exchange in the evaporator 40 is discharged into the room, thereby preventing damage to indoor cooling or deterioration of indoor comfort.

After the heating operation (step S210) is performed for a set time, the surface temperature Ta of the evaporator 40 of the indoor unit is measured (step S230).

It is determined whether the surface temperature Ta of the evaporator 40 of the indoor unit satisfies the set temperature for sterilization (ie, is equal to or greater than the set temperature) (step S240), and the surface temperature Ta is lower than the set temperature for sterilization If not (No in step S240), the process (S250) of increasing the compressive strength of the compressor 10 by one step is repeated until the surface temperature Ta becomes higher than the set temperature for sterilization. .

When the surface temperature Ta of the evaporator 40 of the indoor unit satisfies the set temperature for sterilization (YES in step S240), the surface temperature Ta of the evaporator 40 of the indoor unit is equal to or higher than the set temperature for sterilization The furnace heating operation is continuously maintained for a set time (step S260).

After the lapse of the set time, the high-temperature sterilization operation is terminated (step S270).

On the other hand, after the evaporator high-temperature sterilization operation is finished (step S270), if the evaporator washing operation is first performed by the user's command input during the cooling operation, it is switched back to the normal cooling operation (step S170), and the user's According to the operation end command (step S180), the operation of the air conditioner is terminated (step S190).

Contrary to this, when the evaporator cleaning operation is performed due to the arrival of the reservation time in a state in which the operation of the air conditioner is stopped (“reservation execution” in step S162), the operation of the air conditioner is immediately terminated (step S190). ).

As described above, according to the second embodiment of the present invention, by performing a cycle of freezing → thawing → drying → high-temperature sterilization of the contaminants attached to the surface of the evaporator, which is an indoor unit, the surface cleaning and high-temperature sterilization of the evaporator, which is an indoor unit, can be easily performed. can

In addition, even with an air conditioner capable of reverse cycle, contaminants attached to the surface of the evaporator can be easily washed during indoor cooling operation without performing the reverse cycle of the cooling cycle, and then the reverse cycle can be performed to facilitate high-temperature sterilization. there is.

In the above, specific preferred embodiments of the present invention have been shown and described. However, the present invention is not limited to the above-described embodiments, and various modifications may be made by any person skilled in the art without departing from the gist of the present invention as claimed in the claims.

1: Outdoor unit
2: Indoor unit
4: Refrigerant piping
10: Compressor
20: condenser
22: outdoor unit fan
30: electronically controlled expansion valve
40: evaporator
50: evaporator humidity sensor
52: indoor humidity sensor
54: room temperature sensor
56: evaporator surface temperature sensor
58: outdoor temperature sensor
60: four-way valve
100: control unit
110: input unit

Claims (19)

The compressor 10 compresses the refrigerant, the condenser 20 of the outdoor unit 1 cools the compressed high-temperature and high-pressure refrigerant by external air and condenses it into a liquid, and the refrigerant condensed in the condenser 20 is converted into a low-temperature and low-pressure refrigerant It includes an electronically controlled expansion valve 30 that expands to a refrigerant circuit, an outdoor unit fan 22 for blowing outside air to the condenser 20, and an indoor unit fan 42 for blowing air cooled through the evaporator 40 into the room,
an input unit 110 for a user to input a washing command for the evaporator 40 of the indoor unit 2, a cooling operation/stop command, and selection of an operation mode;
When the evaporator cleaning command is received from the input unit 110 or the stored evaporator cleaning reservation time arrives, the electronically controlled expansion valve is operated during operation in the cooling operation mode or in the cooling operation mode first and after a set time has elapsed An evaporator freezing operation is performed to lower the opening degree of (30) based on a quick freezing mode for rapidly lowering the surface temperature of the evaporator 40 to 0 ° C. or less, and after the surface of the evaporator 40 is frozen, the electronic control The evaporator thawing operation is performed to melt the ice on the surface of the evaporator 40 by completely opening the expansion valve 30, and after thawing, the indoor unit fan 42 is operated to dry the surface of the evaporator 40. Evaporator drying An air conditioner having an evaporator cleaning function of an indoor unit, characterized in that it includes a control unit (100) programmed to perform a driving operation.
The method of claim 1,
It is installed on the refrigerant circuit on the outlet side of the compressor 10 so that the refrigerant exiting the compressor 10 flows to the condenser 20, which is an outdoor unit, in the cooling operation (forward cycle) and for the indoor unit in the heating operation (reverse cycle). The air conditioner having an evaporator cleaning function of an indoor unit, characterized in that it further includes a four-way valve (60) capable of changing the flow direction of the refrigerant to flow to the evaporator (40) to perform a reverse cycle.
3. The method of claim 1 or 2,
an evaporator humidity sensor 50 installed between the evaporator 40 of the indoor unit 2 and the indoor unit fan 42 to measure the humidity of the evaporator 40 and provide it to the control unit 100;
an evaporator surface temperature sensor 56 installed in the indoor unit 2 to measure the surface temperature of the evaporator 40 and provide it to the control unit 100;
an outdoor temperature sensor 58 installed in the outdoor unit 1 to measure the outdoor air temperature and provide it to the control unit 100;
The air conditioner having an evaporator cleaning function of the indoor unit, further comprising an indoor temperature sensor (54) installed in the indoor unit (2) to measure the indoor temperature and provide it to the controller (100).
3. The method of claim 1 or 2,
The control unit 100 measures the outdoor air temperature of the outdoor unit 1 before starting the freezing operation of the evaporator, and when the measured outdoor air temperature exceeds a set temperature, the compressor 10 and the outdoor unit fan 22 An air conditioner having an evaporator cleaning function of an indoor unit, characterized in that it is configured to increase driving strength.
3. The method of claim 1 or 2,
The control unit 100 measures the surface temperature of the evaporator 40 after a set time has elapsed after the start of the freezing operation of the evaporator, and when the surface temperature of the evaporator 40 is higher than the set temperature for rapid freezing, rapid freezing The air conditioner having an evaporator cleaning function of an indoor unit, characterized in that it is configured to further lower the opening degree of the electronically controlled expansion valve (30) by one step until the temperature standard for freezing is satisfied.
3. The method of claim 1 or 2,
The air conditioner having an evaporator cleaning function of the indoor unit, wherein the controller (100) is configured to stop the operation of the compressor (10) during the evaporator thawing operation.
3. The method of claim 1 or 2,
When a set time elapses after the start of the drying operation of the evaporator, the controller 100 measures the humidity of the surface of the evaporator 40, and when the surface humidity of the evaporator 40 does not meet the set drying level, the indoor unit fan (42) An air conditioner having an evaporator cleaning function of an indoor unit, characterized in that it extends the operating time.
3. The method of claim 1 or 2,
and the controller (100) is configured to repeatedly perform the evaporator freezing operation, the evaporator thawing operation, and the evaporator drying operation a plurality of times.
When the evaporator cleaning reservation time stored in the control unit 100 arrives (step S10), or when the user directly manipulates the input unit 110 to input an evaporator cleaning command during the cooling operation (step S20), the air conditioner is currently cooling operation The process of checking whether the driving mode is in operation (step S30);
If the cooling operation is not in progress in the above process (step S3O), the process of executing the cooling operation mode (step S40);
The process of switching to the evaporator washing operation mode during the cooling operation in the process (step S3O) or when a set time elapses after performing the cooling operation mode in the process (step S40) (step S50);
Evaporator freezing that freezes on the surface of the evaporator 40 of the indoor unit by adjusting the opening degree of the electronically controlled expansion valve 30 to be reduced based on the quick freezing mode for rapidly lowering the surface temperature of the evaporator 40 of the indoor unit to 0° C. or less the process of driving (step S100);
After the evaporator freezing operation (step S100) is performed for a set time (step S110), the opening degree of the electronically controlled expansion valve 30 is completely opened to melt the ice on the surface of the evaporator 40 of the indoor unit. process (step S120);
After the thawing operation (step S120) of the evaporator 40 of the indoor unit is performed for a set time (step S130), the driving strength of the indoor unit fan 42 is increased to dry the water on the surface of the evaporator 40 of the indoor unit. a process of performing a drying operation (step S140); and
After performing the evaporator drying operation (step S140) for a set time (step S150), the process of terminating the evaporator washing operation (step S160); A method of operating an air conditioner comprising:
10. The method of claim 9,
After the evaporator cleaning operation is finished (step S160),
If the evaporator washing operation is performed by the user's command input during the cooling operation, the operation is switched back to the normal cooling operation (step S170), and the operation of the air conditioner is terminated according to the user's operation end command (step S180) ( step S190),
If the evaporator cleaning operation is performed due to the arrival of the reserved time in a state in which the operation of the air conditioner is stopped (“reservation execution” in step S162), the process of immediately terminating the operation of the air conditioner (step S190) is performed. The method of operating an air conditioner, characterized in that it further performs.
10. The method of claim 9,
Before starting the evaporator freezing operation (step S100), the outdoor temperature sensor 58 receives the outdoor temperature (step S52), and when the outdoor air temperature is higher than the set temperature, the compressor 10 and the outdoor unit fan 22 An air conditioner operating method characterized in that the rotation speed of the air conditioner is adjusted upward (step S54).
10. The method of claim 9,
After the set time elapses after the start of the evaporator freezing operation (step S110), the surface temperature of the evaporator 40 is measured (step S112), and the surface temperature of the evaporator 40 of the indoor unit is higher than the set temperature for rapid freezing. In the case of (No in step S113), the process (step S114) of lowering the opening degree of the electronically controlled expansion valve 30 by one step and maintaining it for a set time until the temperature standard for rapid freezing is met (step S114) is repeated How to drive an air conditioner.
10. The method of claim 9,
An air conditioner operating method, characterized in that when the evaporator freezing operation (step S100) is performed, the indoor fan (42) is stopped or lowered to a minimum speed.
10. The method of claim 9,
An air conditioner operating method, characterized in that when the evaporator thawing operation (step S120) is performed, the operation of the compressor (10) is stopped.
10. The method of claim 9,
After the above process (step S150), the humidity of the air adjacent to the surface of the evaporator 40 or the evaporator 40 is received from the evaporator humidity sensor 50 (step S152),
If the humidity does not meet the preset reference value (No in step S154), extending the operation time (evaporator drying operation time) of the indoor unit fan 42 until the humidity meets the preset reference value A method of operating an air conditioner, characterized in that.
10. The method of claim 9,
After terminating the evaporator cleaning operation (step S160), the process of switching to the evaporator high-temperature sterilization operation for sterilizing the surface of the evaporator 40 by maintaining the temperature of the evaporator 40 of the indoor unit at a high temperature (step S200);
Entering the high-temperature sterilization operation, the four-way valve 60 is switched to a reverse cycle so that the refrigerant discharged from the compressor 10 flows into the evaporator 40 of the indoor unit, so that the evaporator 40 of the indoor unit plays the role of a condenser for heating the process of driving (step S210);
The process of continuously performing the heating operation for a set time while the surface temperature Ta of the evaporator 40 of the indoor unit is equal to or higher than the set temperature for sterilization (step S260); and
The process of terminating the high-temperature sterilization operation after a set time has elapsed (step S270); An air conditioner operating method, characterized in that it further performs.
17. The method of claim 16,
An air conditioner operating method, characterized in that when the heating operation (step S210) is performed, the indoor unit fan (42) is stopped or the driving intensity is reduced to a minimum speed, and the door flap is closed or kept in a minimum open state.
17. The method of claim 16,
After starting the heating operation (step S210), the surface temperature Ta of the evaporator 40 of the indoor unit is measured (step S230), and it is determined whether the surface temperature Ta satisfies the set temperature for sterilization (step S240). ), a process (S250) of increasing the compressive strength of the compressor (10) one step at a time until the surface temperature (Ta) becomes equal to or higher than the set temperature for sterilization.
17. The method of claim 16,
After the evaporator high-temperature sterilization operation is finished (step S270),
If the evaporator washing operation is performed by the user's command input during the cooling operation, the operation is switched back to the normal cooling operation (step S170), and the operation of the air conditioner is terminated according to the user's operation end command (step S180) ( step S190),
If the evaporator cleaning operation is performed due to the arrival of the reserved time in a state in which the operation of the air conditioner is stopped (“reservation execution” in step S162), the process of immediately terminating the operation of the air conditioner (step S190) is performed. The method of operating an air conditioner, characterized in that it further performs.

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