JP6746804B1 - Air conditioner - Google Patents

Abstract

An air conditioner having an indoor heat exchanger inside is disclosed. The air conditioner has a humidity detection unit that detects the humidity of the air, and a drying operation that dries the interior of the indoor unit when the cumulative period in which the humidity satisfies a predetermined condition at least while the air conditioning operation is stopped exceeds a predetermined time. And a control unit for executing. The above-mentioned predetermined time is characterized by being a value exceeding 24 hours and 192 hours or less.

Description

The present disclosure relates to an air conditioner.

Conventionally, measures against mold that propagates in an indoor heat exchanger of an air conditioner have been studied. For example, Japanese Patent Laying-Open No. 2016-65687 (Patent Document 1) discloses a technique aiming at suppressing the growth of mold on a heat exchanger or the like built in an indoor unit. The air conditioner of Patent Document 1 is provided with a room temperature detecting means for detecting the temperature of the indoor air and a humidity detecting means for detecting the humidity of the indoor air, and after the operation of cooling or defrosting is stopped, the room temperature detecting means and the humidity detecting means. When the cumulative time for detecting a predetermined temperature and humidity condition is 7 hours or more and less than 14 hours, which is a predetermined time or more, one or more of the air blowing operation, the dehumidifying operation, and the heating operation are performed to perform the indoor unit operation. Perform the drying operation to dry the inside. However, if the drying operation is frequently performed, the user may feel uncomfortable, which is not sufficient.

JP, 2016-65687, A

Keiko Abe, Indoor Environmental Evaluation Method Using Dry-drying Mold as Biosensor, J. Antibact. Antifun. Agents, 1993, Vol. 21, No. 10, pp. 557-565

The present disclosure has been made in view of the above points, and the present disclosure is an air conditioner capable of suppressing the growth of mold inside an indoor unit of an air conditioner and reducing discomfort given to a user. The purpose is to provide a machine.

In order to solve the above problems, the present disclosure provides an air conditioner having an indoor heat exchanger inside, which has the following features. The air conditioner includes a humidity detector that detects the humidity of the air. The air conditioner further includes a control unit that performs a drying operation for drying the inside of the indoor unit at least when the cumulative period in which the humidity satisfies a predetermined condition during a stop of the air conditioning operation exceeds a predetermined time. The predetermined time is a value within a range of more than 24 hours and 192 hours or less.

In addition, the problems disclosed by the present application and the means for solving the problems will be made clear by the section of the embodiments for carrying out the invention and the drawings.

According to the present disclosure, it is possible to suppress the growth of mold inside the air conditioner without giving the user discomfort.

FIG. 1 is a front view of an indoor unit, an outdoor unit, and a remote controller (hereinafter, simply referred to as a remote controller) included in an air conditioner according to an embodiment of the present invention. FIG. 2 is a vertical cross-sectional view of an indoor unit included in the air conditioner according to the embodiment of the present invention. FIG. 3 is an explanatory diagram showing a refrigerant circuit of the air conditioner according to the embodiment of the present invention. FIG. 4 is a functional block diagram of the air conditioner according to the embodiment of the present invention. FIG. 5 is a flowchart showing temperature/humidity monitoring control executed by the air conditioner according to the embodiment of the present invention. FIG. 6 is a diagram showing a data structure of a table holding the correction coefficient at the time integration, which is referred to by the air conditioner according to the embodiment of the present invention. FIG. 7 is a diagram illustrating conditions under which the air conditioner according to the embodiment of the present invention performs the drying operation. FIG. 8 is a diagram schematically illustrating a typical mold life cycle.

Hereinafter, embodiments of the present invention will be described with reference to the drawings, but the embodiments of the present invention are not limited to the specific embodiments described below. In the drawings, the same reference numerals indicate the same or corresponding parts.

FIG. 1 is a front view of an indoor unit 10, an outdoor unit 30, and a remote controller 40 included in the air conditioner 100 according to this embodiment. The air conditioner 100 is a device that performs air conditioning by circulating a refrigerant in a refrigeration cycle (heat pump cycle). As shown in FIG. 1, the air conditioner 100 includes an indoor unit 10 installed indoors (air-conditioned space), an outdoor unit 30 installed outdoors, and a remote controller 40 operated by a user.

The indoor unit 10 includes a remote controller transmission/reception unit 11. The remote controller transmission/reception unit 11 transmits/receives a predetermined signal to/from the remote controller 40 by infrared communication or the like. For example, the remote controller transmission/reception unit 11 receives signals such as an operation command, a stop command, a set temperature change command, an operation state change command, and a timer setting command from the remote controller 40. Further, the remote controller transmission/reception unit 11 transmits the detected value of the room temperature and the like to the remote controller 40.

Although not shown in FIG. 1, the indoor unit 10 and the outdoor unit 30 are connected to each other via a refrigerant pipe and a communication line.

FIG. 2 is a vertical cross-sectional view of the indoor unit 10. The indoor unit 10 includes an indoor heat exchanger 12, a drain pan 13, an indoor fan 14, a housing base 15, filters 16t and 16f, in addition to the remote controller transmission/reception unit 11 (see FIG. 1). The front panel 17, the left/right airflow direction plate 18, and the up/down airflow direction plate 19 are provided.

The indoor heat exchanger 12 is a heat exchanger that performs heat exchange between the refrigerant flowing through the heat transfer tube 12g and the indoor air. The drain pan 13 receives water dripping from the indoor heat exchanger 12, and is arranged below the indoor heat exchanger 12. The water dropped on the drain pan 13 is discharged to the outside via a drain hose (not shown).

The indoor fan 14 is, for example, a cylindrical cross-flow fan, and is driven by an indoor fan motor 14a (see FIG. 4). The housing base 15 is a housing in which devices such as the indoor heat exchanger 12 and the indoor fan 14 are installed.

The filters 16t and 16f remove dust from the air taken in through the air suction port h1 and the like, and are installed on the upper side and the front side of the indoor heat exchanger 12. The front panel 17 is a panel installed so as to cover the filter 16f on the front side, and is rotatable frontward about the lower end as an axis. The front panel 17 may not rotate.

The left-right airflow direction plate 18 is a plate-shaped member that adjusts the flow direction of the air blown toward the room in the left-right direction. The left/right airflow direction plate 18 is disposed on the downstream side of the indoor fan 14, and is rotated in the left/right direction by a left/right airflow direction plate motor 21 (see FIG. 4 ). The vertical airflow direction plate 19 is a plate-shaped member that adjusts the flow direction of the air blown toward the room in the vertical direction. The vertical wind direction plate 19 is arranged on the downstream side of the indoor fan 14 and is configured to be rotated in the vertical direction by a vertical wind direction plate motor 22 (see FIG. 4). The vertical wind direction plate 19 is also controlled to open and close the air outlet h3.

The air sucked in through the air suction port h1 exchanges heat with the refrigerant flowing through the heat transfer tube 12g, and the heat-exchanged air is guided to the blowout air passage h2. The air flowing through the blowout air passage h2 is guided in a predetermined direction by the left/right airflow direction plate 18 and the up/down airflow direction plate 19, and is further blown out into the room through the air outlet h3.

FIG. 3 is an explanatory diagram showing the refrigerant circuit Q of the air conditioner 100. The solid arrow in FIG. 3 indicates the flow of the refrigerant during the heating operation. In addition, the dashed arrow in FIG. 3 indicates the flow of the refrigerant during the cooling operation. As shown in FIG. 3, the outdoor unit 30 includes a compressor 31, an outdoor heat exchanger 32, an outdoor fan 33, an outdoor expansion valve 34, and a four-way valve 35.

The compressor 31 is a device that drives a compressor motor 31a to compress a low-temperature low-pressure gas refrigerant and discharge it as a high-temperature high-pressure gas refrigerant. The outdoor heat exchanger 32 is a heat exchanger that performs heat exchange between the refrigerant flowing through the heat transfer pipe (not shown) and the outside air sent from the outdoor fan 33.

The outdoor fan 33 is a fan that sends outside air to the outdoor heat exchanger 32 by driving an outdoor fan motor 33 a (see FIG. 4), and is installed near the outdoor heat exchanger 32. The outdoor expansion valve 34 has a function of reducing the pressure of the refrigerant condensed in the "condenser" (one of the outdoor heat exchanger 32 and the indoor heat exchanger 12). The refrigerant decompressed in the outdoor expansion valve 34 is guided to the "evaporator" (the other of the outdoor heat exchanger 32 and the indoor heat exchanger 12).

The four-way valve 35 is a valve that switches the flow path of the refrigerant according to the operating state of the air conditioner 100. That is, during the cooling operation (see the dashed arrow), the compressor 31, the outdoor heat exchanger 32 (condenser), the outdoor expansion valve 34, and the indoor heat exchanger 12 (evaporator) pass through the four-way valve 35. In the refrigerant circuit Q that is sequentially connected in an annular manner, the refrigerant circulates in the refrigeration cycle.

Further, during the heating operation (see the solid arrow), the compressor 31, the indoor heat exchanger 12 (condenser), the outdoor expansion valve 34, and the outdoor heat exchanger 32 (evaporator) are connected via the four-way valve 35. In the refrigerant circuit Q that is sequentially connected in an annular manner, the refrigerant circulates in the refrigeration cycle.

That is, in the refrigerant circuit Q in which the refrigerant circulates in the refrigeration cycle through the compressor 31, the “condenser”, the outdoor expansion valve 34, and the “evaporator” sequentially, the “condenser” and the “evaporator” One is the outdoor heat exchanger 32, and the other is the indoor heat exchanger 12.

FIG. 4 is a functional block diagram of the air conditioner 100. The indoor unit 10 shown in FIG. 4 includes an imaging unit 23, an environment detection unit 24, an indoor control circuit 25, and a disinfecting substance generation unit 26, in addition to the above configuration.

The image capturing unit 23 captures an image of a room (air-conditioned space), and includes an image capturing element such as a CCD sensor (Charge Coupled Device) or a CMOS sensor (Complementary Metal Oxide Semiconductor). Based on the image pickup result of the image pickup unit 23, the indoor control circuit 25 detects a person in the room (in-room person). By detecting people in the air-conditioned space, each operation can be controlled and maintenance operation can be controlled according to the time the person is in the room, the presence/absence of people, the number and position of people, and the amount of activity. It becomes possible.

The environment detecting unit 24 has a function of detecting the indoor state and the state of the device of the indoor unit 10, and includes an indoor temperature sensor 24a, a humidity sensor 24b, and an indoor heat exchanger temperature sensor 24c. The indoor temperature sensor 24a is a sensor that detects the temperature of the room (air-conditioned space). Although not particularly limited, the indoor temperature sensor 24a is installed closer to the air suction side than the filters 16t and 16f (see FIG. 2). Thereby, when freezing the indoor heat exchanger 12 for cleaning, for example, it is possible to suppress the detection error due to the influence of the heat radiation. The indoor temperature sensor 24a constitutes a temperature detection unit that detects the temperature of air in the present embodiment.

The humidity sensor 24b is a sensor that detects the humidity of the air in the room (air-conditioned space), and is installed at a predetermined position of the indoor unit 10. The humidity sensor 24b is not particularly limited, but is installed at the same location as the indoor temperature sensor 24a and can detect the humidity of the air taken in via the air suction port h1 and the like as the indoor fan 14 rotates. Is configured. The humidity sensor 24b constitutes a humidity detection unit that detects the humidity of air in the present embodiment.

The indoor heat exchanger temperature sensor 24c is a sensor that detects the temperature of the indoor heat exchanger 12 (see FIG. 2), and is installed in the indoor heat exchanger 12. The detected values of the indoor temperature sensor 24a, the humidity sensor 24b, and the indoor heat exchanger temperature sensor 24c are output to the indoor control circuit 25. Although the indoor temperature sensor 24a, the humidity sensor 24b, and the indoor heat exchanger temperature sensor 24c are illustrated in the embodiment to be described, other sensors may be provided.

The disinfectant substance generation unit 26 is an ionizer that generates predetermined ions (for example, OH ⁻ ) that are disinfectant substances, and is installed inside the indoor unit 10. A disinfecting substance generation unit 26 (not shown) can be installed near the air outlet h3 of the indoor unit 10 shown in FIG. Accordingly, the indoor heat exchanger 12 and the like can be sterilized while the indoor fan 14 is stopped, and the sterilized substance can be supplied to the air-conditioned space while the indoor fan 14 is being driven.

Although not shown, the disinfecting substance generation unit 26 includes a needle-shaped discharge electrode and an induction electrode that is curved so as to surround the discharge electrode. Then, the disinfectant substance generation unit 26 applies a predetermined high voltage between the discharge electrode and the dielectric electrode to generate corona discharge, and generates OH ⁻ which is a disinfectant substance.

In addition, in the embodiment to be described, the case where the disinfecting substance generating unit 26 generates OH ⁻ as the disinfecting substance has been described, but the present invention is not limited to this. For example, the disinfecting substance generation unit 26 may generate ions such as O ²⁻ as the disinfecting substance. Further, the sterilized substance generation unit 26 may appropriately set the voltage between the discharge electrode and the dielectric electrode so that OH radicals are generated as the sterilized substance. Further, the voltage between the discharge electrode and the dielectric electrode may be appropriately set so that the disinfecting substance generation unit 26 generates ozone (O ₃ ) as the disinfecting substance. In this way, the indoor heat exchanger 12 can be sterilized by not only the sterilizing substance ions but also radicals and ozone. Further, the disinfecting substance generating unit 26 may generate a disinfecting substance in which OH ⁻ , OH radical, ozone, and the like are mixed. That is, the disinfecting substance generation unit 26 may generate the disinfecting substance that is at least one of predetermined ions, radicals, and ozone.

Although not shown, the indoor control circuit 25 includes electronic circuits such as a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), and various interfaces. Then, the program stored in the ROM is read and expanded in the RAM, and the CPU executes various processes.

As shown in FIG. 4, the indoor control circuit 25 includes a storage unit 25a and an indoor control unit 25b. In addition to a predetermined program, the storage unit 25a stores the image pickup result of the image pickup unit 23, the detection result of the environment detection unit 24, the data received via the remote control transmission/reception unit 11, and the like. The indoor control unit 25b executes a predetermined control based on the data stored in the storage unit 25a.

The outdoor unit 30 includes an outdoor temperature sensor 36 and an outdoor control circuit 37 in addition to the above configuration. The outdoor temperature sensor 36 is a sensor that detects an outdoor temperature (outside air temperature), and is installed at a predetermined location of the outdoor unit 30. Although not shown in FIG. 4, the outdoor unit 30 also includes respective sensors that detect the suction temperature, the discharge temperature, the discharge pressure, and the like of the compressor 31 (see FIG. 3 ). The detection value of each sensor including the outdoor temperature sensor 36 is output to the outdoor control circuit 37.

Although not shown, the outdoor control circuit 37 includes electronic circuits such as a CPU, a ROM, a RAM, and various interfaces, and is connected to the indoor control circuit 25 via a communication line. As shown in FIG. 4, the outdoor control circuit 37 includes a storage unit 37a and an outdoor control unit 37b. In addition to a predetermined program, the storage unit 37a stores a detection value of each sensor including the outdoor temperature sensor 36 and the like. The outdoor control unit 37b controls the compressor motor 31a (that is, the compressor 31), the outdoor fan motor 33a, the outdoor expansion valve 34, and the like based on the data stored in the storage unit 37a. In the following, the indoor control circuit 25 and the outdoor control circuit 37 will be collectively referred to as “control unit K”.

The basic operation of the air conditioner 100 according to the present embodiment will be described below. The air conditioner 100 receives an operation command, a stop command, a set temperature change command, and an operation state change (designation of an operation state such as cooling or heating) command in response to an operation by the user via the remote controller 40. Air conditioning operation. When receiving the operation command, the air conditioner 100 starts the air conditioning operation in the currently set operation state.

The operating states of the air conditioner 100 include cooling operation, heating operation, dehumidifying operation, and blowing operation. Furthermore, there may be an automatic operation in which the cooling operation, the heating operation, the dehumidifying operation, and the blowing operation are automatically switched according to the environment.

In the cooling operation, the control unit K switches the four-way valve 35 so that the indoor heat exchanger 12 acts as an evaporator and the outdoor heat exchanger 32 acts as a condenser, as indicated by a dashed arrow in FIG. Then, the compressor 31 is driven. Then, the control unit K drives the indoor fan 14 to cool the indoor air taken in from the air suction port h1 shown in FIG. 2 by the indoor heat exchanger 12 and control the up/down airflow direction plate 19 to the open state. The air (air-conditioned space) in which the indoor unit 10 is installed is cooled by blowing out the air from the air outlet h3. In the cooling operation, since the indoor heat exchanger 12 acts as an evaporator, the indoor heat exchanger 12 is in a wet state, and the inside of the indoor unit is usually in a high humidity state.

In the heating operation, as indicated by a solid arrow in FIG. 3, the control unit K switches the four-way valve 35 so that the indoor heat exchanger 12 acts as a condenser and the outdoor heat exchanger 32 acts as an evaporator. Then, the compressor 31 is driven. Then, the control unit K drives the indoor fan 14 to heat the indoor air taken in from the air suction port h1 and the like shown in FIG. 2 by the indoor heat exchanger 12, and control the vertical airflow direction vane 19 to be in an open state. By blowing out the air from the air outlet h3, the room (air-conditioned space) in which the indoor unit 10 is installed is heated.

The dehumidification operation may include a so-called reheat dehumidification operation and a cooling dehumidification operation mode, depending on the configuration of the refrigerant circuit.

FIG. 3 also shows a refrigerant circuit configuration capable of reheat dehumidification. In FIG. 3, the indoor heat exchanger 12 is divided into a first indoor heat exchanger 12a and a second indoor heat exchanger 12b. An indoor expansion valve connected to these is provided at a position indicated by V. Further, in the example shown in FIG. 3, the second indoor heat exchanger 12b is located above the first indoor heat exchanger 12a. When performing the above-described normal cooling operation or heating operation, the indoor expansion valve V is controlled to be fully opened, and the opening degree of the outdoor expansion valve 34 is appropriately adjusted.

In the reheat dehumidification operation, the control unit K sets the four-way valve 35 so that the outdoor heat exchanger 32 and the first indoor heat exchanger 12a function as a condenser, and the second indoor heat exchanger 12b functions as an evaporator. Control. Further, the control unit K fully opens the outdoor expansion valve 34 and sets the indoor expansion valve V connected to the first indoor heat exchanger 12a and the second indoor heat exchanger 12b to a predetermined opening degree. Then, the control unit K drives the compressor 31 and the indoor fan 14. As a result, the low-temperature air that has undergone heat exchange in the second indoor heat exchanger 12b, which is an evaporator, is appropriately warmed in the first indoor heat exchanger 12a, which is a condenser, and the room (conditioned space) is dehumidified. .. In the reheat dehumidifying operation, a part of the indoor heat exchanger 12 acts as an evaporator, so a part of the indoor heat exchanger 12 is wet, and the inside of the indoor unit can be in a high humidity state.

In the cooling/dehumidifying operation, the control unit K operates the compressor 31 at a lower frequency than in the case of the above-described cooling operation, suppresses the rotation speed of the indoor fan 14 to be low, and performs the cooling operation with low capacity, thereby reducing the indoor temperature. The humidity is reduced while suppressing the decrease in temperature. In the cooling/dehumidifying operation, although the frequency is suppressed to a low frequency, since the indoor heat exchanger 12 acts as an evaporator as in the cooling operation, the indoor heat exchanger 12 gets wet and the inside of the indoor unit is in a high humidity state. Can be.

In the blowing operation, the control unit K drives the indoor fan 14 without driving the compressor 31 to allow the indoor air taken in from the air suction port h1 or the like to pass through the indoor heat exchanger 12 and move in the vertical wind direction. The plate 19 blows out from the air outlet h3 whose open state is controlled.

During the operation in which at least a part of the indoor heat exchanger 12 cools air (cooling operation, dehumidifying operation), the indoor heat exchanger 12 is condensed, and the inside of the indoor unit is in a high humidity state. Further, after the operation is stopped in this state, the high-humidity state may continue due to the dew condensation water remaining inside the indoor unit 10. Then, if the high-humidity state continues, mold may grow inside the indoor unit 10, which is unsanitary. After the end of the cooling operation or dehumidifying operation, when the time for which the predetermined temperature and humidity conditions are satisfied is detected to be a short time of 24 hours or less (for example, 7 hours or more and less than 14 hours), there is a technique of performing an operation of drying the inside of the indoor unit. Are known. However, the cooling operation and the dehumidifying operation are used by the user because the indoor temperature and humidity are high, and even if the operation is stopped, the drying operation that further warms the room in such an environment can be performed. If performed frequently, there is a risk that the user will feel uncomfortable, and further that there is a risk that the air conditioner 100 may be suspected of malfunction.

Therefore, the air conditioner 100 in the present embodiment constantly (at least during the air conditioning operation stop, preferably during the air conditioning operation and during the air conditioning operation stop) monitors at least the humidity (preferably humidity and temperature) of the air, and is operating. And, during the stop, in response to the cumulative period in which the humidity (preferably temperature and humidity) satisfies a predetermined condition exceeds a predetermined time, a drying operation for drying the inside of the indoor unit is executed. Here, the predetermined time for determining the necessity of the drying operation is a value in the range of more than 24 hours and 192 hours or less, preferably in the range of 120 hours or more and 192 hours or less, and more preferably Is 168 hours (7 days). By configuring the air conditioner 100 to perform a drying operation in which the inside of the indoor unit is brought into a low-humidity state after a cumulative period in which humidity (preferably temperature and humidity) satisfies a predetermined condition exceeds a predetermined time, It is possible to reduce the discomfort given to the user while appropriately suppressing the breeding.

Hereinafter, the control that is executed by the air conditioner 100 according to the present embodiment and that realizes the function of performing the drying operation while monitoring the humidity and the temperature will be described in more detail with reference to FIGS. 5 to 8.

FIG. 5 is a flow chart showing temperature/humidity monitoring control executed by the air conditioner according to the embodiment of the present invention. The control shown in FIG. 5 is described as being executed by the control unit K. The control shown in FIG. 5 describes an embodiment in which both humidity and temperature are monitored.

When supplied with power, the air conditioner 100 first shifts to a stop state, and in response to a drive command from the remote controller 40, starts operating in a predetermined drive state (for example, the drive state set last time). In addition, the air conditioner 100 shifts to the stopped state again in response to the stop command from the remote controller 40. The air conditioner 100 further switches the operating state in response to a command to change the operating state from the remote controller 40. Further, when the room temperature reaches the set temperature during the cooling operation or the dehumidifying operation, the compressor may be stopped (thermo-off), and the operation state may be the same as the blow operation. In addition, the air conditioner 100 performs an automatic filter cleaning operation when the air conditioner 100 is stopped when the integrated time of cooling, heating, dehumidifying operation, etc., exceeds a specified value, and the timer and the image capturing unit 23 prevent the presence of a person. When it is detected, other maintenance operation such as freeze washing may be performed. The function of performing the drying operation while monitoring the humidity and the humidity, which will be described below, is also a kind of the maintenance operation. The control shown in FIG. 5 is described as being executed in the background in parallel with these normal controls and other maintenance operations.

The control shown in FIG. 5 is started from step S100 in response to the power supply to the air conditioner 100. In step S101, the control unit K determines whether or not the air conditioner 100 is in a stopped state. When it is determined in step S101 that the air conditioner 100 is in the stopped state (YES), the control branches to step S102.

In step S102, the control unit K detects the humidity and temperature inside the indoor unit 10 by the humidity sensor 24b and the indoor temperature sensor 24a, respectively, and acquires the current values of humidity and temperature.

The humidity sensor 24b and the room temperature sensor 24a are originally configured to detect the humidity and temperature of the air taken in by the rotation of the indoor fan 14, that is, the air in the room (air-conditioned space) during the normal operation. ing. Here, since the purpose is to acquire the humidity and temperature inside the indoor unit 10, the indoor fan motor 14a is not particularly driven, and the humidity sensor 24b and The indoor temperature sensor 24a detects humidity and temperature.

In the present embodiment, the temperature inside the indoor unit 10 is also detected by the indoor temperature sensor 24a in order to monitor both the temperature and the humidity. Although it is desirable to monitor temperature in addition to humidity, in other embodiments that do not monitor temperature, only humidity by humidity sensor 24b may be acquired.

In step S103, the control unit K determines whether the humidity detected by the humidity sensor 24b and the temperature detected by the indoor temperature sensor 24a satisfy a predetermined condition. Here, as the predetermined condition, a threshold condition for humidity such as 65% or higher can be used, and a threshold condition for temperature such as 10° C. or higher and 35° C. or lower can be used. When it is determined in step S103 that the humidity and the temperature do not satisfy the predetermined conditions (NO), the control is appropriately returned to the step S101 after the elapse of the predetermined standby time. On the other hand, if it is determined in step S103 that the humidity and the temperature satisfy the predetermined conditions (YES), the control proceeds to step S105.

Here, the step S101 is referred to again. When it is determined in step S101 that the vehicle is not in the stopped state (NO), the control branches to step S104. In step S104, the control unit K branches the control depending on whether the operating state is the heating operation, the cooling operation, the dehumidifying operation, or the blowing operation.

When it is determined in step S104 that the operating state is the heating operation (heating), the control is appropriately returned to the step S101 after the standby time has elapsed. Since it is expected that the inside of the indoor unit 10 is in a low humidity state during an operating state in which air is heated using the entire indoor heat exchanger 12, for example, during a heating operation, it is assumed that the humidity and temperature do not satisfy the predetermined conditions. The operating time is excluded from the cumulative period in which the humidity and the temperature described later satisfy the predetermined conditions. The same applies when the thermostat is off during the heating operation.

When it is determined in step S104 that the operating state is either the cooling operation or the dehumidifying operation (cooling/dehumidifying), the control directly proceeds to step S105. Step S105 is a process branched when the humidity and temperature satisfy the predetermined conditions in step S103. This is because the indoor heat exchanger 12 is at least partially dewed in an operating state in which the indoor heat exchanger 12 is at least partially used to cool the air, such as a cooling operation or a dehumidifying operation, and the inside of the indoor unit 10 is This is because it is in a high humidity state. In this case, assuming that the humidity and the temperature satisfy the predetermined condition, the operating time is included in the cumulative period satisfying the predetermined condition described later. Even during the cooling operation, even if the thermostat is off, there is a possibility of dew condensation, so that time is also included in the cumulative period.

When it is determined in step S104 that the operation state is the air blowing operation (air blowing), the control proceeds to step S102. In this case, in step S103, the controller K causes the humidity sensor 24b and the indoor temperature sensor 24a to detect the humidity and the temperature, and acquires the values of the humidity and the temperature.

As described above, here, the purpose is to acquire the humidity and temperature inside the indoor unit 10, but during cooling operation, cooling and heating are not performed, and the temperature and humidity inside the indoor unit are , Considered equivalent to room temperature and humidity. Therefore, in step S104, the control unit K detects the humidity and the temperature by the humidity sensor 24b and the indoor temperature sensor 24a while driving the indoor fan 14.

In step S105, the control unit K integrates the times when the humidity and the temperature satisfy the predetermined conditions to obtain the cumulative period. For example, the accumulating unit 25c is provided in the storage unit 25a of the indoor control circuit 25, and the accumulating period is held by the accumulating unit 25c. When the humidity and the temperature satisfy the predetermined conditions, the control unit K adds a predetermined value to the value currently held by the integrating unit 25c. The method for accumulating the accumulated time is not particularly limited, but the time interval of monitoring (the predetermined waiting time described above) is determined every time the current value is determined to satisfy the predetermined conditions of humidity and temperature. Time) minutes may be added, or the difference between the previous time and the current time may be added when it is continuously determined that the humidity and temperature satisfy the predetermined conditions. Even if the humidity and temperature temporarily stop satisfying the predetermined condition (for example, low humidity condition), the value of the integrating unit 25c is not reset, and when the humidity and temperature again satisfy the predetermined condition. , Accumulation will be restarted. This is because, even if the mold growth is stopped once it is out of the conditions, it is considered that the mold growth resumes when the humidity and the temperature rise again.

At this time, when the humidity and the temperature satisfy the predetermined condition, the time that has been satisfied (10 minutes when the humidity and the temperature satisfy the predetermined condition at the timing, 10 minutes are added as the monitoring time interval of 10 minutes). Can only be accumulated. However, preferably, the easiness of breeding of molds differs depending on the specific humidity and temperature, and therefore the integrated time can be corrected based on the detected humidity and temperature. In a specific embodiment, instead of adding the value of the satisfied time as it is, a value obtained by multiplying the satisfied time by a predetermined correction coefficient can be added to the value currently held by the integrating unit 25c.

FIG. 6 shows a data structure of a table for holding correction coefficients at the time of time integration, which is referred to by the air conditioner according to the embodiment of the present invention. As shown in FIG. 6, the correction coefficient table has each range of humidity (for example, 80 to 90% represents 80% or more and less than 90%) as a row, and each range of temperature (for example, 25 to 30° C., It is represented by a matrix having columns of 25° C. or more and less than 30° C.).

As illustrated in FIG. 6, a value from 0 to 1 is input as the maximum value 1 which is a reference in a region where the humidity is 90% or more and 100% or less and the temperature is 25° C. or more and less than 30° C. As illustrated in FIG. 6, the correction coefficient is 0 in the region where the temperature is low (less than 10° C. in the example) and the region where the temperature is high (40° C. or more in the example). Further, the correction coefficient is 0 in the low humidity region (less than 60% in the example), but in this range, the predetermined condition is not normally satisfied in step S103.

Referring back to FIG. In step S106, the control unit K determines whether or not the cumulative period in which the humidity and the temperature satisfy the predetermined conditions during operation and stop exceeds a threshold value (predetermined time). Here, the threshold value (predetermined time) is a value within a range of more than 24 hours (1 day) and 192 hours (8 days) or less, and more preferably 120 hours (5 days) or more and 192 hours (8 days). ) It is a value within the following range, more preferably 168 hours (7 days). Here, the range of the predetermined time serving as the threshold is a value when the humidity is 90% to 100% and the temperature is 25° C. to 29° C. as a reference (correction coefficient 1).

When it is determined in step S106 that the cumulative period does not exceed the threshold value (predetermined time) (NO), the control is appropriately returned to step S101 after the lapse of the predetermined standby time, and the humidity monitoring is continued. .. On the other hand, if it is determined in step S106 that the cumulative period exceeds the threshold value (predetermined time) (YES), the control proceeds to step S107.

In step S107, the control unit K further determines whether or not the implementation condition is satisfied. Here, the implementation condition includes a condition of whether the humidity and the temperature are within a predetermined range.

FIG. 7 is a diagram illustrating conditions under which the air conditioner according to the embodiment of the present invention performs the drying operation. As shown in FIG. 7, the range specified by both the predetermined range of humidity (A to B) and the predetermined range of temperature (C to D) is defined as the range in which the drying operation is performed. This range is determined, for example, in consideration of the merit that mold can be suppressed by performing the dry operation and the demerit that the user feels uncomfortable. For example, if a dry operation that warms the room is performed when the room is hot and humid during the daytime, the dry operation is performed because the disadvantage is that the user feels uncomfortable. Can be excluded from range. If the drying operation is out of the range, the drying operation is postponed once and, for example, when the indoor temperature at night is relatively low, the execution conditions are satisfied, and the drying operation is performed. Will be. The range in which the drying operation shown in FIG. 7 is performed may be the range in which integration is performed.

Also, if there is a dry operation that warms the room during the cooling or dehumidifying operation, it is likely to cause discomfort to the user.Therefore, dry operation should be performed during the cooling or dehumidifying operation. May not be performed. If the cumulative time exceeds the threshold during the cooling operation or the dehumidifying operation, the operation can be performed after the operation is stopped.

When it is determined in step S107 that the implementation conditions are not satisfied (NO), control is returned to step S101 after a lapse of a predetermined waiting time. On the other hand, if it is determined in step S107 that the implementation conditions are satisfied (YES), the control proceeds to step S108.

In step S108, the control unit K operates the refrigerant circuit Q having the indoor heat exchanger 12 to execute a drying operation for drying the inside of the indoor unit 10. Drying operation can be realized by heating operation, blowing operation, or a combination thereof. Even in the blowing operation, the low humidity condition can be achieved, but the heating operation can more quickly bring the low humidity condition. Therefore, the drying operation preferably includes the heating operation. Further, in another embodiment, the blowing operation and the heating operation can be repeatedly performed.

During the heating operation during the dry operation, the control unit K switches the four-way valve 35 so that the indoor heat exchanger 12 acts as a condenser and the outdoor heat exchanger 32 acts as an evaporator, and the compressor 31. To drive. The control unit K is not particularly limited, but preferably, in the drying operation, it is possible to set the compressor rotation speed and the indoor fan rotation speed lower than the minimum value in the normal operation. The control unit K also preferably performs the drying operation in a state in which the vertical wind direction plate 19 is erected with respect to the blowing direction of the wind as compared with the case of normal operation (the angle of the vertical wind direction plate 19 is higher than normal). Execute. The indoor fan 14 is driven at a lower rotational speed than usual, and the heating operation is performed with the vertical wind direction plate 19 close to the closed state, so that warmed air leaks into the room (air-conditioned space) as much as possible. It is possible to efficiently dry the inside of the indoor unit 10 while preventing this. This makes it possible to dry the interior of the indoor unit 10 while avoiding the user's discomfort as much as possible.

In step S109, the control unit K resets the integrating unit 25c in response to the completion of the drying operation, and appropriately returns the control to step S101 after a lapse of a predetermined waiting time. That is, the cumulative time stored in the cumulative unit 25c is the cumulative time from the first start-up or the cumulative time from the previous drying operation execution.

FIG. 8 is a diagram schematically illustrating a mold life cycle. Molds float in the air and land at new locations. The spores germinate and the hyphae grow while the cells divide. When the hyphae grow and mature, new spores are formed, and the spores are scattered in the air. In such a life cycle, it is known that the period from the implantation of the spores to the scattering of the spores takes about 7 days under conditions where molds can easily reproduce. In order to prevent the growth of mycelia, the drying operation should be carried out early (for example, for 7 hours or more and less than 14 hours under hot and humid conditions where molds easily grow) to suppress the growth of molds. There is a possibility that growth can be suppressed. However, if the dry operation is performed too frequently, it may cause discomfort to the user and further cause the user to suspect a failure. On the other hand, molds propagate greatly due to the scattering of spores.

Therefore, in the present embodiment, at least the cumulative period during which the humidity (preferably humidity and temperature) satisfies the predetermined condition during the air-conditioning operation stop is based on the period from the above-mentioned spores landing until the spores are scattered. , The drying operation for drying the inside of the indoor unit is performed in response to the predetermined time, which is a value within the range of more than 24 hours and 192 hours or less, being exceeded. The predetermined time is preferably a value within the range of 120 hours or more and 192 hours or less, and more preferably 168 hours (7 days). By performing the dry operation before the spores are scattered, it is possible to reduce the discomfort to the user while suitably suppressing the growth of mold.

The drying operation according to the present embodiment is preferably performed in combination with the above-described sterilization operation for filling the room with the sterilization substances such as OH ⁻ , OH radical, and ozone. From the viewpoint of suppressing mold, ozone is preferably used as a disinfecting substance. When combined with the sterilization operation, the drying operation is preferably performed at a lower frequency than the frequency of the sterilization operation for releasing the sterilized substance inside the indoor unit. In other words, while controlling the growth of molds by regularly performing a sterilization operation that releases sterilized substances inside the indoor unit, a drying operation is performed at a relatively low frequency cycle to suppress molds. Preferably. As a result, it is possible to further suppress the mold while reducing the discomfort that is given to the user.

As described above, according to the above-described embodiment, it is possible to provide the air conditioner capable of suppressing the growth of mold inside the indoor unit and reducing the discomfort given to the user.

It should be noted that the embodiment of the present invention is not limited to the above-described embodiment, and various modifications may be included. For example, the above-described embodiments are described in detail for the sake of easy understanding, and are not necessarily limited to those having all the configurations described. Further, a part of the configuration of one embodiment can be replaced with the configuration of another embodiment, and the configuration of another embodiment can be added to the configuration of one embodiment. Further, it is possible to add/delete/replace other configurations with respect to a part of the configurations of the respective embodiments.

Further, a part or all of the above-mentioned respective configurations, functions, processing units, processing means, etc. may be realized by hardware by designing with an integrated circuit, for example. Further, some or all of the above-mentioned respective configurations and functions are described in a legacy programming language such as an assembler, C, C++, C#, Java (registered trademark), an object-oriented programming language, or the like. Information that can be realized by a computer-executable program that realizes each function and that realizes each function, such as a table (hard disk drive), SSD (Solid State Drive) ROM, EEPROM, EPROM, flash memory, etc. Storage device, a flexible disk, a CD-ROM, a CD-RW, a DVD-ROM, a DVD-RAM, a DVD-RW, a Blu-ray disc, an SD (registered trademark) card, an MO, or a device-readable recording medium, or It can be distributed through a telecommunication line.

Further, a part or all of the above-mentioned respective configurations and functions can be mounted on a programmable device (PD) such as a field programmable gate array (FPGA), and the above-mentioned functional unit is PD. Circuit configuration data (bit stream data) to be downloaded to the PD for realizing the above, HDL (Hardware Description Language) for generating the circuit configuration data, VHDL (Very High Speed Integrated Circuits Hardware Description Language), Verilog-HDL, etc. It can be distributed by a recording medium as data described by. The control lines and information lines shown are those considered necessary for explanation, and not all control lines and information lines are shown on the product. In reality, it may be considered that almost all the configurations are connected to each other.

DESCRIPTION OF SYMBOLS 10... Indoor unit, 11... Remote control transmission/reception part, 12... Indoor heat exchanger, 13... Drain pan, 14... Indoor fan, 15... Housing base, 16... Filter, 17... Front panel, 18... Left/right wind direction plate, 19... Vertical wind direction plate, 21... Horizontal wind direction plate motor, 22... Vertical wind direction plate motor, 23... Imaging unit, 24... Environment detection unit, 24a... Indoor temperature sensor, 24b... Humidity sensor, 24c... Indoor heat exchanger temperature sensor , 25... Indoor control circuit, 25a... Storage section, 25b... Indoor control section, 26... Sterilized substance generating section, 30... Outdoor unit, 31... Compressor, 31a... Compressor motor, 32... Outdoor heat exchanger, 33 ...Outdoor fan, 33a...outdoor fan motor, 34...outdoor expansion valve, 35...four-way valve, 36...outdoor temperature sensor, 37...outdoor control circuit, 37a...storage section, 37b...outdoor control section, 40...remote control, 100... Air conditioner, h1...Air inlet, h2...Blowout air passage, h3...Air outlet, Q...Refrigerant circuit

Claims (11)

An air conditioner including an indoor heat exchanger,
A humidity detector that detects the humidity of the air,
At least a control unit that executes a drying operation for drying the inside of the indoor unit in response to a cumulative period in which the humidity satisfies a predetermined condition while the air conditioning operation is stopped exceeds a predetermined time,
The predetermined time is a value within a range of more than 24 hours and 192 hours or less, and the control unit further performs a cycle with a higher frequency than the frequency of performing the drying operation, in the indoor unit interior. An air conditioner, which is configured to perform a sterilization operation for releasing a sterilization substance to the air conditioner. Including a temperature detection unit that detects the temperature of air,
The air conditioner according to claim 1, wherein the control unit executes the drying operation in response to a cumulative period in which the temperature and the humidity satisfy predetermined conditions exceeding the predetermined time. The air conditioner according to claim 1 or 2, wherein the predetermined time is a value within a range of 120 hours or more and 192 hours or less. The air conditioner according to any one of claims 1 to 3, wherein the period in which the predetermined condition is satisfied is a cumulative time from a first start-up or a previous drying operation is performed. The time to be integrated is corrected based on the detected humidity and temperature, and the range of the predetermined time is a value when the humidity is 90% or more and 100% or less and the temperature is 25°C or more and less than 30°C as a reference. The air conditioner according to Item 3 or 4. The cumulative period includes a time when at least humidity satisfies a predetermined condition during an air conditioning operation, and an operating time in an operation state in which at least a part of the indoor heat exchanger cools air is a cumulative time when the predetermined condition is satisfied. The air conditioner according to claim 1, wherein the air conditioner is included in a period. 7. The operating time in the operating state of heating air using the indoor heat exchanger is excluded from the period in which the predetermined condition is satisfied, 7. Air conditioner. The control unit performs the drying operation when a period of time when the predetermined condition is satisfied exceeds the predetermined time and when the humidity and the temperature are within a predetermined range. The air conditioner according to any one of Items 1 to 7. The humidity detection unit is configured to detect the humidity of the air taken in by the rotation of the indoor fan during normal operation, and the control unit controls the humidity by the humidity detection unit with the indoor fan stopped. 9. The air conditioner according to claim 1, wherein the air conditioner is detected. The air conditioner according to any one of claims 1 to 9, wherein the control unit sets a compressor rotation speed and an indoor fan rotation speed that are lower than a minimum value in a normal operation during the drying operation. The air conditioner includes an airflow direction plate that opens and closes an outlet, and the control unit performs the drying operation in a state in which the airflow direction plate is set up in a blowing direction of the wind as compared with a case of a normal operation time. The air conditioner according to any one of claims 1 to 10.

Images