JP7212283B2 - air conditioner - Google Patents

Description

Air conditioner that performs dehumidification operation

2. Description of the Related Art Conventionally, there is an air conditioner having a refrigerant circuit configured by connecting a compressor, an outdoor heat exchanger, an expansion mechanism, and an indoor heat exchanger. Then, in this air conditioner, as shown in Patent Document 1 (Japanese Patent Application Laid-Open No. 2002-333186), the indoor humidity detected by the humidity sensor is used to transfer the refrigerant enclosed in the refrigerant circuit to the compressor and the outdoor heat exchanger. Some dehumidification operations are performed by circulating in the order of the unit, expansion mechanism, and indoor heat exchanger.

An air conditioner according to a first aspect includes a refrigerant circuit, an indoor fan, and a controller. A refrigerant circuit is configured by connecting a compressor, an outdoor heat exchanger, an expansion mechanism, and an indoor heat exchanger. The indoor fan sends indoor air to the indoor heat exchanger. The control unit performs a dehumidification operation in which the refrigerant enclosed in the refrigerant circuit is circulated through the compressor, the outdoor heat exchanger, the expansion mechanism, and the indoor heat exchanger in this order. The control unit performs thermo-off to stop the compressor when a predetermined thermo-off condition is satisfied during the dehumidifying operation. The control unit has a thermo-off temperature condition based on the indoor temperature and a thermo-off humidity condition based on the indoor humidity as determination elements for determining whether the thermo-off condition is satisfied during the dehumidifying operation. During dehumidifying operation, if the thermo-off temperature condition is met but the thermo-off humidity condition is not met, the controller does not stop the compressor, and the evaporation temperature of the refrigerant in the indoor heat exchanger exceeds the dew point temperature of the indoor air. Control the capacity of the compressor and the air volume of the indoor fan so that it falls below. The control unit activates the compressor to perform a dehumidifying operation when a predetermined thermo-on condition is satisfied during the thermo-off. The controller has a thermo-on temperature condition based on the room temperature as a determination element for determining whether the thermo-on condition is satisfied.

An air conditioner according to a second aspect is the air conditioner according to the first aspect, wherein the controller selectively performs a dehumidifying operation and a cooling operation other than the dehumidifying operation.

An air conditioner according to a third aspect is the air conditioner according to the second aspect, wherein the controller stops the compressor when a predetermined thermo-off condition is satisfied during cooling operation. . Further, the control unit has only the thermo-off temperature condition based on the indoor temperature as a determination element for determining whether or not the thermo-off condition is satisfied during the cooling operation.

An air conditioner according to a fourth aspect is the air conditioner according to the third aspect, wherein the control unit, during the dehumidifying operation, when the state in which the indoor temperature reaches the thermo-off temperature or less continues for a predetermined time, , is determined to satisfy the thermo-off temperature condition. Further, the control unit determines that the thermo-off temperature condition is satisfied when the room temperature reaches the thermo-off temperature or lower during the cooling operation.

An air conditioner according to a fifth aspect is the air conditioner according to the third or fourth aspect, wherein the thermo-off temperature of the thermo-off temperature condition during dehumidifying operation is lower than the thermo-off temperature of the thermo-off temperature condition during cooling operation. value.

An air conditioner according to a sixth aspect is the air conditioner according to any one of the second to fifth aspects, wherein the number of rotations of the indoor fan during dehumidifying operation is lower than the number of rotations of the indoor fan that can be set during cooling operation. It is

An air conditioner according to a seventh aspect is the air conditioner according to the sixth aspect, wherein the rotation speed of the indoor fan during the dehumidifying operation is equal to or lower than the minimum rotation speed among the rotation speeds that can be set during the cooling operation.

An air conditioner according to an eighth aspect is the air conditioner according to any one of the second to seventh aspects, wherein the evaporation temperature during the dehumidifying operation is equal to or lower than the evaporation temperature during the cooling operation.

An air conditioner according to a ninth aspect is the air conditioner according to the first to eighth aspects, wherein the control unit is configured to be able to select a plurality of dehumidification operation modes with different dehumidification levels as the dehumidification operation. .

An air conditioner according to a tenth aspect is the air conditioner according to the ninth aspect, wherein the evaporation temperature changes according to the dehumidification level of the selected dehumidification operation mode.

An air conditioner according to an eleventh aspect is the air conditioner according to the first to tenth aspects, further comprising an indoor humidity sensor for detecting indoor humidity. When the indoor humidity sensor is abnormal, the control unit performs the dehumidifying operation using a substitute value as the indoor humidity instead of the detected value of the indoor humidity sensor.

An air conditioner according to a twelfth aspect has a refrigerant circuit, an indoor fan, and a controller. A refrigerant circuit is configured by connecting a compressor, an outdoor heat exchanger, an expansion mechanism, and an indoor heat exchanger. The indoor fan sends indoor air to the indoor heat exchanger. The control unit selectively performs a dehumidifying operation and a cooling operation other than the dehumidifying operation. The control unit performs thermo-off to stop the compressor when a predetermined thermo-off condition is satisfied during the dehumidifying operation. The control unit has a thermo-off temperature condition based on the indoor temperature and a thermo-off humidity condition based on the indoor humidity as determination elements for determining whether or not the thermo-off condition is satisfied during the dehumidifying operation. During dehumidifying operation, if the thermo-off temperature condition is met but the thermo-off humidity condition is not met, the controller does not stop the compressor, and the evaporation temperature of the refrigerant in the indoor heat exchanger exceeds the dew point temperature of the indoor air. Control the capacity of the compressor and the air volume of the indoor fan so that it falls below.

1 is a schematic configuration diagram of an air conditioner according to an embodiment of the present disclosure; FIG. 1 is an external perspective view of an indoor unit that constitutes an air conditioner; FIG. FIG. 3 is a schematic side cross-sectional view of the indoor unit, and is a cross-sectional view taken along line IOI of FIG. 2; 3 is a control block diagram of the air conditioner; FIG. 4 is a control flowchart during cooling operation. 4 is a control flowchart (mode selection) during dehumidification operation; 4 is a control flow chart during dehumidification operation (dehumidification operation modes L, M, and H). It is a flowchart which shows the process at the time of indoor humidity sensor abnormality.

Hereinafter, embodiments of an air conditioner will be described based on the drawings.

(1) Device Configuration FIG. 1 is a schematic configuration diagram of an air conditioner 1 according to an embodiment of the present disclosure.

<Overall>
The air conditioner 1 is a device that air-conditions a room such as a building using a vapor compression refrigeration cycle. The air conditioner 1 mainly has an outdoor unit 2 , an indoor unit 3 , and a liquid refrigerant communication pipe 4 and a gas refrigerant communication pipe 5 that connect the outdoor unit 2 and the indoor unit 3 . The vapor compression refrigerant circuit 10 of the air conditioner 1 is configured by connecting the outdoor unit 2 and the indoor unit 3 via the liquid refrigerant communication pipe 4 and the gas refrigerant communication pipe 5 .

<Outdoor unit>
The outdoor unit 2 is installed outdoors (on the roof of a building, near the outer wall of the building, etc.). The outdoor unit 2 is connected to the indoor unit 3 via the liquid refrigerant communication pipe 4 and the gas refrigerant communication pipe 5 as described above, and constitutes a part of the refrigerant circuit 10 . The outdoor unit 2 mainly has a compressor 21 , a four-way switching valve 23 , an outdoor heat exchanger 24 and an expansion valve 25 .

The compressor 21 is a mechanism that compresses low-pressure refrigerant in the refrigeration cycle to high pressure. Here, as the compressor 21, a closed type compressor in which a positive displacement compression element (not shown) such as a rotary type or a scroll type is rotationally driven by a compressor motor 22 is used. Further, here, the compressor motor 22 can be controlled in rotational speed (frequency) by an inverter or the like, so that the capacity of the compressor 21 can be controlled.

The four-way switching valve 23 is a valve for switching the direction of the refrigerant flow when switching between cooling or dehumidifying operation and heating operation. The four-way switching valve 23 connects the discharge side of the compressor 21 and the gas side of the outdoor heat exchanger 24 during cooling operation or dehumidifying operation, and also connects the indoor heat exchanger 31 (described later) through the gas refrigerant communication pipe 5. ) and the suction side of the compressor 21 (see the solid line of the four-way switching valve 23 in FIG. 1). Further, during heating operation, the four-way switching valve 23 connects the discharge side of the compressor 21 and the gas side of the indoor heat exchanger 31 via the gas refrigerant connecting pipe 5, and also connects the gas side of the outdoor heat exchanger 24. and the suction side of the compressor 21 (see the dashed line of the four-way switching valve 23 in FIG. 1).

The outdoor heat exchanger 24 is a heat exchanger that functions as a refrigerant radiator during cooling operation or dehumidifying operation, and functions as a refrigerant evaporator during heating operation. The outdoor heat exchanger 24 is connected to the expansion valve 25 on the liquid side and to the four-way switching valve 23 on the gas side.

The expansion valve 25 reduces the pressure of the high-pressure liquid refrigerant radiated in the outdoor heat exchanger 24 before sending it to the indoor heat exchanger 31 during cooling operation or dehumidification operation, and reduces the pressure of the high-pressure liquid refrigerant radiated in the indoor heat exchanger 31 during heating operation. It is an expansion mechanism capable of reducing the pressure of the refrigerant before sending it to the outdoor heat exchanger 24 . Here, as the expansion valve 25, an electric expansion valve whose degree of opening can be controlled is used.

The outdoor unit 2 is also provided with an outdoor fan 26 for sucking outdoor air into the unit, supplying the outdoor air to the outdoor heat exchanger 24, and then discharging the outdoor air outside the unit. That is, the outdoor heat exchanger 24 is a heat exchanger that uses the outdoor air as a cooling source or a heating source to release heat or evaporate the refrigerant. The outdoor fan 26 is rotationally driven by an outdoor fan motor 27 .

Further, the outdoor unit 2 is provided with various sensors. Specifically, the outdoor unit 2 is provided with a suction pressure sensor 28 that detects the suction pressure Ps of the compressor 21 .

<Refrigerant connecting pipe>
The refrigerant communication pipes 4 and 5 are refrigerant pipes that are constructed on site when the air conditioner 1 is installed in an installation location such as a building. One end of the liquid refrigerant communication pipe 4 is connected to the expansion valve 25 side of the indoor unit 2 , and the other end of the liquid refrigerant communication pipe 4 is connected to the liquid side of the indoor heat exchanger 31 of the indoor unit 3 . One end of the gas refrigerant communication pipe 5 is connected to the four-way switching valve 23 side of the indoor unit 2, and the other end of the gas refrigerant communication pipe 5 is connected to the gas side of the indoor heat exchanger 31 of the indoor unit 3. .

<Indoor unit>
The indoor unit 3 is installed indoors (inside the building). The indoor unit 3 is connected to the outdoor unit 2 via the liquid refrigerant communication pipe 4 and the gas refrigerant communication pipe 5 as described above, and constitutes a part of the refrigerant circuit 10 . The indoor unit 3 mainly has an indoor heat exchanger 31 and an indoor fan 32 .

Here, as the indoor unit 3, a type of indoor unit called a ceiling-embedded type is adopted. The indoor unit 3, as shown in FIGS. 2 and 3, has a casing 41 that accommodates components therein. The casing 41 is composed of a casing main body 41a and a decorative panel 42 arranged below the casing main body 41a. The casing main body 41a is arranged to be inserted into an opening formed in the ceiling U, as shown in FIG. The decorative panel 42 is arranged so as to be fitted into the opening of the ceiling U. Here, FIG. 2 is an external perspective view of the indoor unit 3. FIG. FIG. 3 is a schematic side cross-sectional view of the indoor unit 3, and is a cross-sectional view taken along the line IOI of FIG.

The casing main body 41a is a substantially octagonal box-shaped body in which long sides and short sides are alternately formed in plan view, and the lower surface thereof is open. The casing main body 41 a has a substantially octagonal top plate 43 in which long sides and short sides are alternately formed continuously, and side plates 44 extending downward from the peripheral edge of the top plate 43 .

The decorative panel 42 is a plate-like body that is substantially polygonal (here, substantially rectangular) in plan view and constitutes the lower surface of the casing 41, and is mainly a panel main body fixed to the lower end portion of the casing main body 41a. 42a. The panel main body 42a has an intake port 45 for sucking indoor air, and an outlet 46 for blowing air into the room surrounding the intake port 45 in plan view. The intake port 45 is a substantially rectangular opening. The suction port 45 is provided with a suction grill 47 and a suction filter 48 for removing dust in the air sucked from the suction port 45 . The air outlets 46 include a plurality of (here, four) side air outlets 46a formed along each side of the square of the panel main body 42a and a plurality of (here, four) formed at the corners of the panel main body 42a. , there are four corner outlets 46b. Each side air outlet 46a is provided with a plurality of (here, four) wind direction changing blades 49 capable of changing the angle of the vertical wind direction of the air blown into the room from each side air outlet. is provided. The wind direction changing blade 49 is a plate-like member elongated along the longitudinal direction of the side outlet 46a. The wind direction changing blade 49 can be rotated around a longitudinal axis to change the wind direction angle in the vertical direction.

An indoor heat exchanger 31 and an indoor fan 32 are mainly arranged inside the casing main body 41a.

The indoor heat exchanger 31 is a heat exchanger that functions as a refrigerant evaporator during cooling operation or dehumidifying operation, and functions as a refrigerant radiator during heating operation. The outdoor heat exchanger 31 has its liquid side connected to the liquid refrigerant communication pipe 4 and its gas side connected to the gas refrigerant communication pipe 5 . The indoor heat exchanger 31 is a heat exchanger bent to surround the indoor fan 32 in plan view. The indoor heat exchanger 31 exchanges heat between the indoor air sucked into the casing body 41a by the indoor fan 32 and the refrigerant. A drain pan 31 a is arranged below the indoor heat exchanger 31 to receive drain water produced by condensation of moisture in the indoor air by the indoor heat exchanger 31 . The drain pan 31a is attached to the lower portion of the casing main body 41a.

The indoor fan 32 is a fan that sucks room air into the casing body 41a through the intake port 45 of the decorative panel 42 and blows the air from the casing body 41a into the room through the outlet port 46 of the decorative panel 42 . That is, the indoor heat exchanger 31 is a heat exchanger that uses the indoor air as a cooling source or a heating source to release heat or evaporate the refrigerant. Here, as the indoor fan 32, a centrifugal fan is used that sucks indoor air from below and blows it out toward the outer peripheral side in plan view. The indoor fan 32 is rotationally driven by an indoor fan motor 33 provided in the center of the top plate 43 of the casing main body 41a. Further, here, the indoor fan motor 33 can be controlled in rotational speed (frequency) by an inverter or the like, so that the air volume of the indoor fan 32 can be controlled. Specifically, as the air volume of the indoor fan 32, the maximum air volume H, the medium air volume M smaller than the air volume H, the small air volume L smaller than the air volume M, and the minimum air volume smaller than the air volume L Air volume LL of air volume is prepared. Here, the air volume LL is an air volume that cannot be set by the person in the room using the remote control 60 (described later).

Further, the indoor unit 3 is provided with various sensors. Specifically, the indoor unit 3 is provided with an indoor temperature sensor 34 and an indoor humidity sensor 35 for detecting the temperature (indoor temperature Tr) and humidity (indoor humidity Hr) of the indoor air sucked into the indoor unit 3. ing.

(2) Control Configuration FIG. 4 is a control block diagram of the air conditioner 1. As shown in FIG.

<Overall>
The air conditioner 1 as a refrigerating device includes a controller 6 in which an outdoor controller 20, an indoor controller 30, and a remote controller 60 are connected via a transmission line or a communication line in order to control the operation of components. have. The outdoor controller 20 is provided in the indoor unit 2 . The indoor controller 30 is provided in the indoor unit 3 . A remote control 60 is provided indoors. Here, the controllers 20 and 30 and the remote controller 60 are wiredly connected via transmission lines or communication lines, but may be wirelessly connected.

<Outdoor controller>
The outdoor controller 20 is provided in the outdoor unit 2 as described above, and mainly has an outdoor CPU 20a, an outdoor transmission section 20b, and an outdoor storage section 20c. The indoor controller 20 can receive the detection signal of the suction pressure sensor 28 .

The outdoor CPU 20a is connected to the outdoor transmission section 20b and the outdoor storage section 20c. The heat source side transmission section 20b transmits control data and the like to and from the indoor side control section 30a. The outdoor storage unit 20c stores control data and the like. The outdoor side CPU 20a transmits, reads and writes control data and the like via the outdoor side transmission section 20b and the outdoor side storage section 20c, while transmitting the constituent devices 21, 23, 25, 26, etc. provided in the outdoor unit 2. control the operation of

<Indoor side controller>
The indoor control unit 30 is provided in the indoor unit 3 as described above, and mainly includes the indoor CPU 30a, the indoor transmission unit 30b, the indoor storage unit 30c, and the indoor communication unit 30d. have. The indoor controller 30 can receive detection signals from the indoor temperature sensor 34 and the indoor humidity sensor 35 .

The indoor CPU 30a is connected to the indoor transmission section 30b, the indoor storage section 30c, and the indoor storage section 30d. The indoor transmission unit 30 b transmits control data and the like to the outdoor control unit 20 . The indoor storage unit 30b stores control data and the like. The indoor communication unit 30 c transmits and receives control data and the like to and from the remote control 60 . The indoor CPU 30a transmits, reads, writes, and transmits/receives control data and the like via the indoor transmission section 30b, the indoor storage section 30c, and the indoor communication section 30d, while performing the transmission, reading, writing, and transmission of control data. 32, 49, etc. are controlled.

<Remote control>
The remote control 60 is provided indoors as described above, and mainly includes a remote control CPU 61, a remote control storage unit 62, a remote control communication unit 63, a remote control operation unit 64, and a remote control display unit 65. there is

The remote control CPU 61 is connected to the remote control communication section 62 , the remote control storage section 63 , the remote control operation section 64 and the remote control display section 65 . The remote control communication unit 62 transmits and receives control data and the like to and from the indoor communication unit 30c. The remote controller storage unit 63 stores control data and the like. A remote control operation unit 64 receives an input such as a control command from a user. The remote control display unit 65 displays operation and the like. The remote control CPU 61 receives input of operation commands, control commands, etc. via the remote control operation unit 64 , reads and writes control data, etc. in the remote control storage unit 63 , and displays the operation state and control state on the remote control display unit 65 . While performing such operations, a control command or the like is issued to the indoor control unit 30 via the remote control communication unit 62 .

As described above, the air conditioner 1 as a refrigeration system has the control unit 6 that controls the operation of the components. The control unit 6 controls the components 21, 23, 25, 26, 32, 49, etc. based on the detection signals of the suction pressure sensor 28, the indoor temperature sensor 34, and the indoor humidity sensor 35, etc. Air-conditioning operation such as dehumidification operation and heating operation and various controls can be performed.

(3) Basic Operation Next, the basic operation (heating operation, cooling operation, and dehumidifying operation) of the air conditioner 1 will be described.

<Heating operation>
The air conditioner 1 can perform a heating operation as an air conditioning operation. In the heating operation, the controller 6 receives a command for the heating operation via the remote controller 64, and controls the operation of the constituent devices 21, 23, 25, 26, 32, 49, etc. of the outdoor unit 2 and the outdoor unit 3. done by

In the heating operation, the outdoor heat exchanger 24 functions as a refrigerant evaporator and the indoor heat exchanger 31 functions as a refrigerant radiator (that is, the four-way switching valve 23 in FIG. 1 is indicated by the dashed line). The four-way switching valve 23 is switched so that the four-way switching valve 23 is turned on.

In the refrigerant circuit 10 in such a state, low-pressure refrigerant in the refrigeration cycle is sucked into the compressor 21, compressed to high pressure in the refrigeration cycle, and then discharged. A high-pressure refrigerant discharged from the compressor 21 is sent to the indoor heat exchanger 31 through the four-way switching valve 23 and the gas refrigerant communication pipe 5 . The high-pressure refrigerant sent to the indoor heat exchanger 31 exchanges heat with the indoor air supplied by the indoor fan 32 in the indoor heat exchanger 31 to radiate heat. As a result, the indoor air is heated and blown out into the room. The high-pressure refrigerant that has radiated heat in the indoor heat exchanger 31 is sent to the expansion valve 25 through the liquid refrigerant communication pipe 4 and decompressed to a low pressure in the refrigeration cycle. The low-pressure refrigerant decompressed by the expansion valve 25 is sent to the outdoor heat exchanger 24 . The low-pressure refrigerant sent to the outdoor heat exchanger 24 exchanges heat with the outdoor air supplied by the outdoor fan 26 in the outdoor heat exchanger 24 and evaporates. The low-pressure refrigerant evaporated in the outdoor heat exchanger 24 is sucked into the compressor 21 again through the four-way switching valve 23 . Thus, in the heating operation, the control unit 6 causes the refrigerant enclosed in the refrigerant circuit 10 to circulate through the compressor 21, the indoor heat exchanger 31, the expansion valve 25, and the outdoor heat exchanger 24 in this order. It's like

<Cooling operation>
The air conditioner 1 can perform a cooling operation as an air conditioning operation. In the cooling operation, the controller 6 receives a command for the cooling operation via the remote controller 64, and controls the operation of the constituent devices 21, 23, 25, 26, 32, 49, etc. of the outdoor unit 2 and the outdoor unit 3. done by

In the cooling operation, the outdoor heat exchanger 24 functions as a refrigerant radiator, and the indoor heat exchanger 31 functions as a refrigerant evaporator (that is, the state indicated by the solid line of the four-way switching valve 23 in FIG. 1). The four-way switching valve 23 is switched so that the four-way switching valve 23 is turned on.

In the refrigerant circuit 10 in such a state, low-pressure refrigerant in the refrigeration cycle is sucked into the compressor 21, compressed to high pressure in the refrigeration cycle, and then discharged. A high-pressure refrigerant discharged from the compressor 21 is sent to the outdoor heat exchanger 24 through the four-way switching valve 23 . The high-pressure refrigerant sent to the outdoor heat exchanger 24 exchanges heat with the outdoor air supplied by the outdoor fan 26 in the outdoor heat exchanger 24 to radiate heat. The high-pressure refrigerant that has released heat in the outdoor heat exchanger 24 is sent to the expansion valve 25 and decompressed to a low pressure in the refrigeration cycle. The low-pressure refrigerant decompressed by the expansion valve 25 is sent to the indoor heat exchanger 31 through the liquid refrigerant communication pipe 4 . The low-pressure refrigerant sent to the indoor heat exchanger 31 exchanges heat with the indoor air supplied by the indoor fan 32 in the indoor heat exchanger 31 and evaporates. As a result, the indoor air is cooled and blown into the room. The low-pressure refrigerant evaporated in the indoor heat exchanger 31 is sucked into the compressor 21 again through the gas refrigerant communication pipe 5 and the four-way switching valve 23 . Thus, in the cooling operation, the control unit 6 causes the refrigerant enclosed in the refrigerant circuit 10 to circulate through the compressor 21, the outdoor heat exchanger 24, the expansion valve 25, and the indoor heat exchanger 31 in this order. It's like

<Dehumidification operation>
The air conditioner 1 can perform a dehumidifying operation as an air conditioning operation. In the dehumidifying operation, the control unit 6 receives a dehumidifying operation command via the remote control operation unit 64, and controls the operation of the constituent devices 21, 23, 25, 26, 32, 49, etc. of the outdoor unit 2 and the outdoor unit 3. done by

In the dehumidifying operation, as in the cooling operation, the outdoor heat exchanger 24 functions as a refrigerant radiator and the indoor heat exchanger 31 functions as a refrigerant evaporator (that is, the four-way switching in FIG. 1). The four-way switching valve 23 is switched so that the state indicated by the solid line of the valve 23 is reached.

In the refrigerant circuit 10 in such a state, low-pressure refrigerant in the refrigeration cycle is sucked into the compressor 21, compressed to high pressure in the refrigeration cycle, and then discharged. A high-pressure refrigerant discharged from the compressor 21 is sent to the outdoor heat exchanger 24 through the four-way switching valve 23 . The high-pressure refrigerant sent to the outdoor heat exchanger 24 exchanges heat with the outdoor air supplied by the outdoor fan 26 in the outdoor heat exchanger 24 to radiate heat. The high-pressure refrigerant that has released heat in the outdoor heat exchanger 24 is sent to the expansion valve 25 and decompressed to a low pressure in the refrigeration cycle. The low-pressure refrigerant decompressed by the expansion valve 25 is sent to the indoor heat exchanger 31 through the liquid refrigerant communication pipe 4 . The low-pressure refrigerant sent to the indoor heat exchanger 31 exchanges heat with the indoor air supplied by the indoor fan 32 in the indoor heat exchanger 31 and evaporates. As a result, the indoor air is dehumidified and blown into the room. The low-pressure refrigerant evaporated in the indoor heat exchanger 31 is sucked into the compressor 21 again through the gas refrigerant communication pipe 5 and the four-way switching valve 23 . Thus, in the dehumidifying operation, the controller 6 causes the refrigerant enclosed in the refrigerant circuit 10 to circulate through the compressor 21, the outdoor heat exchanger 24, the expansion valve 25, and the indoor heat exchanger 31 in this order. It's like

(4) Control during cooling operation In the cooling operation described above, the following controls are performed. FIG. 5 is a flow chart of cooling operation.

<Step ST1 (Thermo ON)>
In step ST1, that is, during the cooling operation (when operating the compressor 21 to circulate the refrigerant, during thermo-on), the control unit 6 sets the evaporation temperature Te of the refrigerant in the refrigerant circuit 10 to the target evaporation temperature. Capacity control is performed to control the capacity of the compressor 21 so as to be Tecs. Further, the control unit 6 sets the air volume of the indoor fan 32 to the set air volume (here, air volume L, air volume M and air volume H).

The capacity control of the compressor 21 increases the rotation speed (frequency) of the compressor 21 to increase the capacity of the compressor 21 when the evaporation temperature Te of the refrigerant is higher than the target evaporation temperature Tecs. When the evaporating temperature Te is lower than the target evaporating temperature Tecs, the rotation speed (frequency) of the compressor 21 is reduced to reduce the capacity of the compressor 21 .

Here, the control unit 6 determines the target evaporation temperature Tecs based on the temperature difference ΔTr obtained by subtracting the target room temperature Trs from the room temperature Tr. Specifically, the control unit 6 determines the target evaporation temperature Tecs to be lower as the temperature difference ΔTr is larger. The target room temperature Trs is set by input from the remote control operation section 64 of the remote control 60 by a person in the room. The evaporation temperature Te of the refrigerant is obtained by converting the suction pressure Ps into the saturation temperature of the refrigerant. The refrigerant evaporation temperature Te represents the low-pressure refrigerant in the refrigeration cycle that flows from the outlet of the expansion valve 25 to the suction side of the compressor 21 via the indoor heat exchanger 31 during cooling operation. It means the temperature obtained by converting the pressure (evaporation pressure Pe of the refrigerant in the refrigerant circuit 10) into the saturation temperature of the refrigerant, or the saturation temperature of the refrigerant in the indoor heat exchanger 31 functioning as a refrigerant evaporator. Therefore, when a temperature sensor is provided in the indoor heat exchanger 31, the temperature of the refrigerant detected by this temperature sensor may be used as the evaporation temperature Te of the refrigerant.

Here, the state quantity to be controlled in the capacity control is the evaporation temperature Te, but it may be the evaporation pressure Pe. In this case, the target evaporation pressure Pecs corresponding to the target evaporation temperature Tecs may be used as the control target value. Using the evaporating pressure Pe and the target evaporating pressure Pecs in this capacity control is the same as using the evaporating temperature Te and the target evaporating temperature Tecs.

<Step ST2 (determination of whether the thermo-off condition is satisfied)>
In step ST2, the controller 6 determines whether or not the thermostat OFF condition is satisfied while the thermostat is ON in step ST1.

The control unit 6 has a thermo-off temperature condition based on the room temperature Tr as a determination element for determining whether or not the thermo-off condition is satisfied. The control unit 6 determines that the thermo-off condition is satisfied when the thermo-off temperature condition is satisfied, and determines that the thermo-off condition is not satisfied when the thermo-off temperature condition is not satisfied. Specifically, the control unit 6 determines that the temperature conditions for the thermostat-off are satisfied when the indoor temperature Tr becomes lower than the thermostat-off temperature Trcf while the thermostat is on, and the indoor temperature Tr becomes the thermostat-off temperature. If it is higher than Trcf, it is determined that the thermo-off temperature condition is not satisfied. Here, the thermo-off temperature Trcf is a value obtained by adding the thermo-off temperature difference ΔTrcf to the target room temperature Trs. The thermostat off temperature difference ΔTrcf is set to a value between -1 degree and +1 degree.

Here, whether or not the thermo-off condition is satisfied is determined based on whether the room temperature Tr has reached the thermo-off temperature Trcf, but the present invention is not limited to this. For example, it may be determined whether or not the temperature difference ΔTr obtained by subtracting the target indoor temperature Trs from the indoor temperature Tr has reached the thermo-off temperature difference ΔTrcf. It is the same as judging by whether or not

<Step ST3 (thermo off)>
When the controller 6 determines in step ST2 that the thermo-off condition is satisfied because the room temperature Tr reaches the thermo-off temperature Trcf or lower, in step ST3, the compressor 21 is stopped to stop the circulation of the refrigerant. Stop cooling operation (thermo off).

<Step ST4 (determination of whether the thermo-on condition is satisfied)>
In step ST4, the controller 6 determines whether or not the thermo-on condition is satisfied while the thermo-off is in step ST3.

The controller 6 has a thermo-on temperature condition based on the room temperature Tr as a determination element for determining whether the thermo-on condition is satisfied. If the thermo-on temperature condition is satisfied, the control unit 6 determines that the thermo-on condition is satisfied, and if the thermo-on temperature condition is not satisfied, the control unit 6 determines that the thermo-on condition is not satisfied. Specifically, when the room temperature Tr rises and reaches the thermo-on temperature Trcn or more while the thermostat is off, the control unit 6 determines that the thermo-on temperature condition is satisfied, and the room temperature Tr reaches the thermo-on temperature. If it is lower than Trcn, it is determined that the thermo-on temperature condition is not satisfied. Here, the thermo-on temperature Trcn is a value obtained by adding the thermo-on temperature difference ΔTrcn to the target room temperature Trs. The thermo-on temperature difference ΔTrcn is set to a value between 0 degrees and +2 degrees.

Here, whether or not the thermo-on condition is satisfied is determined by whether or not the room temperature Tr reaches the thermo-on temperature Trcn, but the present invention is not limited to this. For example, it may be determined whether or not the temperature difference ΔTr obtained by subtracting the target room temperature Trs from the room temperature Tr reaches the thermo-on temperature difference ΔTrcn. It is the same as judging by whether or not

If the controller 6 determines in step ST4 that the thermo-on condition is satisfied, it returns to step ST1, starts the compressor 21, and performs cooling operation (thermo-on).

(5) Control during dehumidification operation In the dehumidification operation described above, the following control is performed. FIG. 6 is a flowchart of dehumidifying operation (mode selection), and FIG. 7 is a flowchart of dehumidifying operation (dehumidifying operation modes L, M, and H).

<Step ST11 (mode selection)>
Here, a plurality of dehumidification operation modes with different dehumidification levels are prepared as the dehumidification operation in order to meet the dehumidification level needs of the people in the room. Here, the dehumidifying level means the degree of the indoor humidity Hr to be obtained by the dehumidifying operation, and the lower the indoor humidity Hr to be obtained by the dehumidifying operation, the higher the dehumidifying level. Specifically, as the dehumidification operation mode, the dehumidification operation mode L with the lowest dehumidification level, the dehumidification operation mode M with a medium dehumidification level higher than the dehumidification level of the dehumidification operation mode L, and the dehumidification operation mode M The controller 6 is provided with three dehumidifying operation modes H, which are high in level. Here, the selection of the dehumidifying operation mode is made by inputting from the remote controller operation section 64 of the remote controller 60 by the person in the room in step ST11.

<Step ST12 (Dehumidifying operation mode L)>
When the dehumidifying operation mode L is selected in step ST11, the control section 6 performs control in step ST12 (that is, steps ST21 to ST27).

-Step ST21 (Thermo ON)-
In step ST21, that is, during the dehumidification operation (during the operation of operating the compressor 21 to circulate the refrigerant, during thermo-on), the evaporation temperature Te of the refrigerant in the refrigerant circuit 10 reaches the target evaporation temperature. Capacity control is performed to control the capacity of the compressor 21 so that it becomes Teds. Further, the controller 6 performs air volume control to limit the air volume of the indoor fan 32 to the air volume L or the air volume LL during the thermo-on of step ST21, unlike step ST1 during the cooling operation.

The capacity control of the compressor 21 is the same as step ST1 during the cooling operation, except that the target evaporation temperature Tecs is set to the target evaporation temperature Teds. Therefore, the description of the capacity control of the compressor 21 is omitted here. Here, the target evaporation temperature Teds is set to a value equal to or lower than the target evaporation temperature Tecs.

-Step ST22 (Determination 1 of whether or not the thermo-off condition is satisfied)-
In step ST22, the controller 6 determines whether or not the thermostat OFF condition is satisfied while the thermostat is ON in step ST21.

The control unit 6 has a first thermo-off temperature condition based on the indoor temperature Tr and a thermo-off humidity condition based on the indoor humidity Hr as determination elements for determining whether or not the thermo-off condition is satisfied. Then, when both the first thermo-off temperature condition and the thermo-off humidity condition are satisfied, the control unit 6 determines that the thermo-off condition is satisfied, and satisfies one or both of the first thermo-off temperature condition and the thermo-off humidity condition. If not, it is determined that the thermo-off condition is not satisfied. That is, in the dehumidifying operation mode L, unlike step ST2 during the cooling operation, not only the thermo-off temperature condition but also the thermo-off humidity condition are considered to determine whether or not the thermo-off condition is satisfied.

Specifically, the control unit 6 sets the first thermo-off temperature when the indoor temperature Tr decreases and the indoor temperature Tr reaches the first thermo-off temperature TrdfL1 or lower during the thermo-on and continues for a predetermined time tL. If it is determined that the condition is satisfied, and if the room temperature Tr is higher than the first thermo-off temperature TrdfL1 or if the state in which the room temperature Tr has reached the first thermo-off temperature TrdfL1 or less does not continue for a predetermined time tL, the first thermo-off It is determined that the temperature condition is not satisfied. Here, the first thermostat off temperature TrdfL1 is a value obtained by adding the first thermostat off temperature difference ΔTrdfL1 to the target room temperature Trs. The first thermo-off temperature difference ΔTrdfL1 is set to a value of about −1 degree to +1 degree, and the predetermined time tL is set to a value of about several tens of seconds to several minutes. Further, the first thermo-off temperature TrdfL1 (=target room temperature Trs+first thermo-off temperature difference ΔTrdfL1) may be the same value as the thermo-off temperature Trcf during cooling operation (=target room temperature Trs+thermo-off temperature difference ΔTrcf), It can be a low value.

In addition, the control unit 6 determines that the humidity conditions for the thermostat-off are satisfied when the indoor humidity Hr becomes low and reaches the target indoor humidity HrsL while the thermostat is on, and the indoor humidity Hr is higher than the target indoor humidity HrsL. is also high, it is determined that the thermo-off humidity condition is not satisfied. Here, the target indoor humidity HrsL is set to a value with a low dehumidification level (that is, a high relative humidity value) of about 60% to 70% when the dehumidifying operation mode L is selected in step ST11.

Here, whether or not the thermo-off condition is satisfied is determined by whether the room temperature Tr has reached the first thermo-off temperature TrdfL1 and whether the room humidity Hr has reached the target room humidity HrsL. It is not limited to this. For example, whether the temperature difference ΔTr obtained by subtracting the target indoor temperature Trs from the indoor temperature Tr has reached the first thermo-off temperature difference ΔTrdfL1, and whether the humidity difference ΔHr obtained by subtracting the target indoor humidity Hrs from the indoor humidity Hr is 0 (zero). It may be determined by whether the Determination based on these temperature difference ΔTr and humidity difference ΔHr is the same as determining whether the room temperature Tr has reached the first thermo-off temperature TrdfL1 and whether the room humidity Hr has reached the target room humidity HrsL. is.

-Step ST23 (Thermo off)-
In step ST22, the controller 6 satisfies the thermo-off condition when the indoor humidity Hr reaches the target indoor humidity HrsL when the indoor temperature Tr has reached the first thermo-off temperature TrdfL1 or lower continuously for a predetermined time tL. If so, in step ST23, the compressor 21 is stopped to stop the circulation of the refrigerant and stop the dehumidifying operation (thermo off). The control unit 6 also turns off the thermostat when it is determined in step ST27 (described later) that the room temperature Tr reaches the second thermooff temperature TrdfL2 or lower to satisfy the thermooff condition.

-Step ST24 (determination of whether the thermo-on condition is satisfied)-
While the thermostat is off in step ST23, the controller 6 determines in step ST24 whether or not the thermostat-on condition is satisfied.

The controller 6 has a thermo-on temperature condition based on the room temperature Tr as a determination element for determining whether the thermo-on condition is satisfied, as in step ST4 during the cooling operation. If the thermo-on temperature condition is satisfied, the control unit 6 determines that the thermo-on condition is satisfied, and if the thermo-on temperature condition is not satisfied, the control unit 6 determines that the thermo-on condition is not satisfied. Specifically, when the room temperature Tr rises and reaches the thermo-on temperature TrdnL or higher while the thermostat is off, the control unit 6 determines that the thermo-on temperature condition is satisfied, and the room temperature Tr reaches the thermo-on temperature. If it is lower than TrdnL, it is determined that the thermo-on temperature condition is not satisfied. The thermo-on temperature TrdnL is a value obtained by adding the thermo-on temperature difference ΔTrdnL to the target room temperature Trs. The thermo-on temperature difference ΔTrdnL may be the same value as the thermo-on temperature Trcn (=target room temperature Trs+thermo-on temperature difference ΔTrcn) during cooling operation, or may be a lower value.

Here, whether or not the thermo-on condition is satisfied is determined by whether or not the room temperature Tr reaches the thermo-on temperature TrdnL, but the present invention is not limited to this. For example, it may be determined whether or not the temperature difference ΔTr obtained by subtracting the target room temperature Trs from the room temperature Tr reaches the thermo-on temperature difference ΔTrdnL. It is the same as judging by whether or not

Then, when it is determined in step ST24 that the thermo-on condition is satisfied, the control section 6 returns to step ST21, starts the compressor 21, and performs the dehumidifying operation (thermo-on).

-Step ST25 (Determination 2 of whether or not the thermo-off condition is satisfied)-
If the thermo-off conditions (both the first thermo-off temperature condition and the thermo-off humidity condition) of step ST22 are not satisfied during the thermo-on of step ST21, the control unit 6 satisfies the first thermo-off temperature condition in step ST25, but the thermo-off A determination is made as to whether or not the humidity conditions are not met. That is, the control unit 6 determines whether or not the thermo-off humidity condition is not satisfied when the first thermo-off temperature condition is satisfied. Then, if the first thermo-off temperature condition is satisfied but the thermo-off humidity condition is not satisfied, the control unit 6 does not turn off the thermostat and performs dehumidification continuation control in step ST26.

-Step ST26 (thermo-on, continuous dehumidification control)-
In step ST26, the controller 6 continues capacity control for controlling the capacity of the compressor 21 and air volume control for the indoor fan 32 so that the evaporation temperature Te of the refrigerant in the refrigerant circuit 10 reaches the target evaporation temperature Teds. However, here, unlike the capacity control and the air volume control in step ST21, the controller 6 controls the capacity of the compressor 21 so that the evaporation temperature Te of the refrigerant in the indoor heat exchanger 31 is lower than the dew point temperature Trw of the indoor air. And the air volume of the indoor fan 32 is controlled. Here, the air volume of the indoor fan 32 is controlled to the minimum air volume LL, and the capacity of the compressor 21 is controlled to be small within a range where the evaporation temperature Te is lower than the dew point temperature Trw.

Here, the controller 6 determines the target evaporation temperature Teds based on the dew point temperature Trw. Specifically, the controller 6 calculates the dew point temperature Trw from the indoor temperature Tr and the indoor humidity Hr. Then, the control unit 6 determines the target evaporation temperature Teds by subtracting the predetermined temperature difference ΔTrw from the calculated dew point temperature Trw. That is, the controller 6 determines the target evaporation temperature Teds to be lower than the dew point temperature Trw.

Then, when the indoor humidity Hr reaches the target indoor humidity HrsL as the indoor dehumidification is continued by such continuous dehumidification control, the controller 6 sets both the first thermo-off temperature condition and the thermo-off humidity condition in step ST22. is satisfied, the thermostat is turned off in step ST23.

-Step ST27 (determination 3 of whether or not the thermo-off condition is satisfied)-
If the thermo-off conditions (both the first thermo-off temperature condition and the thermo-off humidity condition) of step ST22 are not satisfied during the dehumidification continuation control of step ST26, the control unit 6 determines whether the thermo-off humidity condition is not satisfied in step ST27. By satisfying the second thermo-off temperature condition, it is determined whether or not the thermo-off condition is satisfied.

The control unit 6 further has a second thermo-off temperature condition lower than the first thermo-off temperature condition as a determination element for determining whether the thermo-off condition is satisfied. Then, if the second thermo-off temperature condition is satisfied even if the thermo-off humidity condition is not satisfied, the control unit 6 determines that the thermo-off condition is satisfied, and if the thermo-off humidity condition and the second thermo-off temperature condition are not satisfied. , it is determined that the thermo-off condition is not satisfied. That is, during the continuous dehumidification control in step ST26, in step ST22, it is determined not only whether the first thermo-off temperature condition and the thermo-off humidity condition are satisfied, but also whether the second thermo-off temperature condition is satisfied. ing.

Specifically, the control unit 6 determines that the second thermo-off temperature condition is met when the indoor temperature Tr further decreases during the continuous dehumidification control and reaches the second thermo-off temperature TrdfL2 or lower. , it is determined that the second thermo-off temperature condition is not satisfied when the room temperature Tr is higher than the second thermo-off temperature TrdfL2. Here, the second thermostat off temperature TrdfL2 is a value obtained by adding the second thermostat off temperature difference ΔTrdfL2 to the target room temperature Trs. Then, the second thermo-off temperature difference ΔTrdfL2 is set to a value lower than the first thermo-off temperature TrdfL1 (for example, a value of about -3 to -2 degrees).

Here, whether or not the thermo-off condition is satisfied is determined based on whether the room temperature Tr has reached the second thermo-off temperature TrdfL2, but the present invention is not limited to this. For example, it may be determined whether or not the temperature difference ΔTr obtained by subtracting the target indoor temperature Trs from the indoor temperature Tr has reached the second thermo-off temperature difference ΔTrdfL2. Determination based on this temperature difference ΔTr is the same as determination based on whether the room temperature Tr has reached the second thermo-off temperature TrdfL2.

<Step ST13 (Dehumidifying operation mode M)>
When the dehumidifying operation mode M is selected in step ST11, the control section 6 performs control in step ST13 (that is, steps ST31 to ST37).

Here, the processing of steps ST31 to ST37 of the dehumidifying operation mode M is the same as the processing of steps ST21 to ST27 of the dehumidifying operation mode L. Therefore, here, the letter "L" in the description of steps ST21 to ST27 of the dehumidifying operation mode L is replaced with "M", and steps ST21 to ST27 are replaced by ST31 to ST37, thereby explaining steps ST31 to ST37. omitted.

However, when the dehumidifying operation mode M is selected in step ST11, the target indoor humidity HrsM is lower than the target indoor humidity HrsL of the dehumidifying operation mode L (for example, a moderate relative humidity of about 50% to 60%). value).

In the dehumidifying operation mode M, the first thermo-off temperature TrdfM1 (first thermo-off temperature difference ΔTrdfM1) may be set to the same value as the first thermo-off temperature TrdfL1 (first thermo-off temperature difference ΔTrdfL1) in the dehumidifying operation mode L. , a low value (for example, the value of the first thermo-off temperature difference ΔTrdfM1 is about −1.5 degrees to +0.5 degrees). The predetermined time tM may be set to the same value as the predetermined time tL in the dehumidifying operation mode L, or may be set to a longer value. The thermo-on temperature TrdnM (=target room temperature Trs+thermo-on temperature difference ΔTrdnM) may be set to the same value as the thermo-on temperature TrdnL (=target room temperature Trs+thermo-on temperature difference ΔTrdnL) in the dehumidifying operation mode L, or may be set to a lower value. . The second thermostat-off temperature TrdfM2 (=target room temperature Trs+second thermostat-off temperature difference ΔTrdfM2) may be set to the same value as the second thermostat-off temperature TrdfL2 (=target room temperature Trs+second thermostat-off temperature difference ΔTrdfL2) in dehumidifying operation mode L. However, it may be set to a low value (for example, a value of about -3.5 degrees to -2.5 degrees for the second thermo-off temperature difference ΔTrdfM2).

<Step ST14 (Dehumidifying operation mode H)>
When the dehumidifying operation mode H is selected in step ST11, the control section 6 performs control in step ST14 (that is, steps ST41 to ST47).

Here, the processing of steps ST41 to ST47 in the dehumidifying operation mode H is the same as the processing of steps ST21 to ST27 in the dehumidifying operation mode L. Therefore, here, the letter "L" in the description of steps ST21 to ST27 in the dehumidifying operation mode L is replaced with "H", and steps ST21 to ST27 are replaced by ST41 to ST47, thereby explaining steps ST41 to ST47. omitted.

However, when the dehumidifying operation mode H is selected in step ST11, the target indoor humidity HrsH is a value lower than the target indoor humidity HrsL, HrsM of the dehumidifying operation modes L, M (for example, about 40% to 50% lower). relative humidity value).

In the dehumidifying operation mode H, the first thermo-off temperature TrdfH1 (first thermo-off temperature difference ΔTrdfH1) is the same as the first thermo-off temperatures TrdfL1 and TrdfM1 (first thermo-off temperature differences ΔTrdfL1 and ΔTrdfM1) in the dehumidifying operation modes L and M. However, a low value (for example, a value in which the first thermo-off temperature difference ΔTrdfH1 is about -2 degrees to 0 degrees) may also be used. The predetermined time tH may be set to the same value as the predetermined times tL, tM in the dehumidifying operation modes L, M, or may be set to a longer value. The thermo-on temperature TrdnH (=target room temperature Trs+thermo-on temperature difference .DELTA.TrdnH) may be set to the same value as the thermo-on temperatures TrdnL and TrdnM (=target room temperature Trs+thermo-on temperature difference .DELTA.TrdnL, .DELTA.TrdnM) in the dehumidifying operation modes L and M. It can be a low value. Second thermostat-off temperature TrdfH2 (=target room temperature Trs+second thermostat-off temperature difference ΔTrdfH2) is divided into second thermostat-off temperatures TrdfL2 and TrdfM2 (=target room temperature Trs+second thermostat-off temperature differences ΔTrdfL2 and ΔTrdfM2) in dehumidifying operation modes L and M. The same value may be used, or a lower value (for example, a value in which the second thermostat OFF temperature difference ΔTrdfH2 is about −4 degrees to −3 degrees).

(6) Processing when Indoor Humidity Sensor Abnormality The indoor humidity Hr detected by the indoor humidity sensor 35 is used during control of the dehumidifying operation described above. Specifically, the control unit 6 uses the room humidity Hr detected by the room humidity sensor 35 in the process of determining whether or not the thermostat-off humidity condition is satisfied in steps ST22, ST32, and ST42, and in steps ST26, ST36, and steps ST26, ST36, It is used to calculate the dew point temperature Trw in the continuous dehumidification control process in ST46. Therefore, when an abnormality occurs in the indoor humidity sensor 35, the control unit 6 cannot obtain the detected value of the indoor humidity Hr, and the dehumidifying operation using the indoor humidity Hr cannot be performed. Here, the abnormality of the indoor humidity sensor 35 includes not only breakage or malfunction of the indoor humidity sensor 35 but also disconnection of the connection line between the indoor humidity sensor 35 and the control unit 6 .

Therefore, here, when the indoor humidity sensor 35 is abnormal, the controller 6 uses a substitute value instead of the detected value of the indoor humidity sensor 35 as the indoor humidity Hr to perform the dehumidifying operation. In particular, since a plurality of dehumidification operation modes with different dehumidification levels can be selected as the dehumidification operation here, the control unit 6 substitutes for the indoor humidity Hr according to the dehumidification level of the selected dehumidification operation mode. I am trying to change the value.

Specifically, as shown in FIG. 8, when the controller 6 detects an abnormality in the indoor humidity sensor 35 in step ST61, in steps ST62 to ST65, the selected dehumidifying operation mode is set as the indoor humidity Hr. , the processing is performed using substitute values HreL, HreM, and HreH corresponding to .

Here, the substitute value HreL in the dehumidifying operation mode L is set so that in the process of determining whether the thermostat-off humidity condition is satisfied in step ST22, the process of determining whether the thermostat-off humidity condition is satisfied can be shifted to the dehumidification continuation control process in step ST26 without turning off the thermostat. It is set to a value higher than the target indoor humidity HrsL in the dehumidifying operation mode L. Moreover, the substitute value HreL in the dehumidifying operation mode L is set lower than the target indoor humidity HrsL so that the target evaporation temperature Teds is set lower by calculating the dew point temperature Trw lower in the continuous dehumidification control process in step ST26. is set to a slightly higher value. The substitute value HreL in the dehumidifying operation mode L is set to a value higher than the target indoor humidity HrsL (set to about 60% to 70%) and the difference between them is small (for example, within 10%). . Also, the substitute value HreM in the dehumidifying operation mode M and the substitute value HreH in the dehumidifying operation mode H are set similarly to the substitute value HreL in the dehumidifying operation mode L. For example, the substitute value HreM in the dehumidifying operation mode M is set to a value higher than the target indoor humidity HrsM (set to about 50% to 60%) and the difference between them is small (for example, within 10%). The substitute value HreH in the dehumidifying operation mode H is set to a value higher than the target indoor humidity HrsH (set to about 40% to 50%) and the difference between them is small (for example, within 10%). be done. Thus, here, as the dehumidification level of the selected dehumidifying operation mode increases in the order of L, M, and H, the substitute value for the indoor humidity Hr is changed to decrease in the order of HreL, HreM, and HreH. It has become so. As a result, in the determination processing of steps ST22, ST32, and ST42 as to whether or not the thermostat-off humidity condition is met, the process of step ST26, ST36, and ST46 can be shifted to the dehumidification continuation control processing without turning off the thermostat. , in the continuous dehumidification control, the target evaporation temperature Teds can be set so that the dehumidification level of the selected dehumidification operation mode decreases in the order of L, M, and H.

Further, here, the controller 6 is configured to notify the abnormality of the indoor humidity sensor 35 when the abnormality of the indoor humidity sensor 35 is detected.

Specifically, as shown in FIG. 8, when the controller 6 detects an abnormality in the indoor humidity sensor 35 in step ST61, in step ST66, the process of notifying the abnormality in the indoor humidity sensor 35 is performed. I have to.

Here, the notification of the abnormality may be made by sound or a lamp, or by displaying sentences, words, or codes indicating the abnormality on the screen of the remote controller display section 65 of the remote controller 60 or the like. There may be. In addition, the notification by the display on the screen of the remote control display unit 65 may be displayed on the screen of the remote control display unit 65 at the same time as the occurrence of the abnormality, or the remote control operation unit 64 may switch the screen or the like. It may be displayed when the screen of the remote control display unit 65 is switched to a screen for displaying an abnormality by issuing an instruction.

(7) Features Next, features of the air conditioner 1 will be described.

<A>
Here, as described above, in the air conditioner 1 that performs the dehumidifying operation using the indoor humidity sensor 35, when the indoor humidity sensor 35 is abnormal, the indoor humidity Hr is substituted for the value detected by the indoor humidity sensor 35. Dehumidifying operation is performed using the values HreL, HreM, and HreH (see steps ST61 to ST65).

Specifically, during the control of the dehumidification operation, the control unit 6 uses the substitute values HreL, HreM, and HreH as the room humidity Hr in the processing for determining whether or not the thermostat OFF humidity condition is satisfied in steps ST22, ST32, and ST42. Also, in the continuous dehumidification control process of steps ST26, ST36, and ST46, the substitute values HreL, HreM, and HreH are used to calculate the dew point temperature Trw, so that these processes can be performed smoothly. .

As a result, even if the detection value of the indoor humidity sensor 35 is not obtained, the same method (steps ST21 to ST27, ST31 to ST37, ST41 The dehumidification operation can be performed in the process of ˜ST47).

<B>
Further, here, as described above, the control unit 6 is configured to be able to select a plurality of dehumidifying operation modes with different dehumidifying levels (see steps ST11 to ST14).

As a result, dehumidification operation suitable for the needs of the dehumidification level of the people in the room can be performed here.

<C>
Further, here, as described above, the control unit 6 changes the substitute values HreL, HreM, and HreH of the indoor humidity Hr according to the dehumidification level of the selected dehumidification operation mode (see steps ST62 to ST65). ).

Specifically, in any of the dehumidifying operation modes L, M, and H, each substitute value HreL, HreM, and HreH is set to a value higher than the corresponding target indoor humidity HrsL, HrsM, and HrsH. , ST32, and ST42, the thermostat is not turned off, and the dehumidification continuation control process of steps ST26, ST36, and ST46 is performed. Further, by setting the substitute values HreL, HreM, and HreH so that the dehumidification level of the selected dehumidifying operation mode decreases in the order of L, M, and H, The target evaporation temperature Teds is set so that the dehumidification level of the selected dehumidifying operation mode decreases in the order of L, M, and H (that is, the dehumidification capacity increases in the order of L, M, and H). .

Thereby, even if the detection value of the indoor humidity sensor 35 is not obtained, the dehumidification operation can be performed according to the selected dehumidification level.

<D>
Further, here, as described above, the control unit 6 is configured to notify the abnormality of the indoor humidity sensor 35 (see step ST66).

Here, it is possible to prompt the people in the room to repair or replace the indoor humidity sensor 35 .

<E>
Here, when the process (see steps ST61 to ST65) for when the indoor humidity sensor 35 is abnormal is performed, the continuation of dehumidification after the first thermo-off temperature condition (thermo-off temperature condition) is satisfied, The temperature Tr may become too low. That is, since the thermo-off humidity condition is not met in steps ST22, ST32, and ST42 by the processing when the indoor humidity sensor 35 is abnormal, the dehumidifying operation is continued, and the indoor temperature Tr becomes too low, causing the occupants to This means that you may feel uncomfortable.

Therefore, here, as described above, the control unit 6 further sets the second thermo-off temperature condition, which is on the lower temperature side than the first thermo-off temperature condition (thermo-off temperature condition), as a determination element for determining whether or not the thermo-off condition is satisfied. have. Then, the control unit 6 determines that the thermo-off condition is met when the second thermo-off temperature condition on the low temperature side is met even if the thermo-off humidity condition is not met (see steps ST27, ST37, and ST47). .

As a result, here, even when the process (see steps ST61 to ST65) is performed when the indoor humidity sensor 35 is abnormal, the indoor temperature Tr Before the temperature becomes too low, the thermostat can be turned off (see steps ST23, ST33, and ST43). Therefore, in the same way as when the indoor humidity sensor 35 does not have an abnormality, the amount of dehumidification is increased by continuing dehumidification after the first thermostat off temperature condition is satisfied, and the lack of dehumidification in the room makes the occupants uncomfortable. In addition, excessive continuation of dehumidification after the first thermo-off temperature condition is satisfied is suppressed, and the possibility that the room temperature Tr becomes too low and the occupants feel uncomfortable can be reduced. .

(8) Modification <A>
In the above embodiment, three dehumidification operation modes L, M, and H can be selected as a plurality of dehumidification operation modes with different dehumidification levels. mode, or four or more dehumidifying operation modes.

<B>
In the above-described embodiment and modification A, the air conditioner 1 having the dehumidifying operation performed until the first thermo-off temperature condition is satisfied and the dehumidifying operation performed after the first thermo-off temperature condition is satisfied is taken as an example. However, it is not limited to this, and if the air conditioner performs dehumidifying operation using the indoor humidity sensor, the control content during dehumidifying operation is applied. can be applied depending on

<C>
In the above-described embodiment and modifications A and B, the indoor unit 3 that houses the indoor heat exchanger 31 is a ceiling-embedded type. Other types of indoor units such as wall-mounted units may also be used.

Although embodiments of the present disclosure have been described above, it will be appreciated that various changes in form and detail may be made without departing from the spirit and scope of the present disclosure as set forth in the appended claims. .

INDUSTRIAL APPLICABILITY The present disclosure is widely applicable to air conditioners that perform a dehumidifying operation using indoor humidity detected by a humidity sensor.

REFERENCE SIGNS LIST 1 air conditioner 6 control unit 10 refrigerant circuit 21 compressor 24 outdoor heat exchanger 25 expansion valve (expansion mechanism)
31 indoor heat exchanger 35 indoor humidity sensor

Japanese Patent Application Laid-Open No. 2002-333186

Claims (12)

a refrigerant circuit (10) configured by connecting a compressor (21), an outdoor heat exchanger (24), an expansion mechanism (25), and an indoor heat exchanger (31);
an indoor fan (32) for sending indoor air to the indoor heat exchanger;
a control unit (6) for performing a dehumidification operation in which the refrigerant enclosed in the refrigerant circuit is circulated in the order of the compressor, the outdoor heat exchanger, the expansion mechanism, and the indoor heat exchanger;
and
The control unit performs thermo-off to stop the compressor when a predetermined thermo-off condition is satisfied during the dehumidifying operation,
The control unit has a thermo-off temperature condition based on room temperature and a thermo-off humidity condition based on room humidity as determination elements for determining whether or not the thermo-off condition is satisfied during the dehumidifying operation,
During the dehumidification operation, if the thermostat-off temperature condition is satisfied but the thermostat-off humidity condition is not satisfied, the control unit does not stop the compressor, and reduces the evaporation temperature of the refrigerant in the indoor heat exchanger. controls the capacity of the compressor and the air volume of the indoor fan so that is below the dew point temperature of the indoor air;
The control unit activates the compressor to perform the dehumidification operation when a predetermined thermo-on condition is satisfied during the thermo-off,
The control unit has a thermo-on temperature condition based on room temperature as a determination element for determining whether the thermo-on condition is satisfied.
An air conditioner (1). The control unit selectively performs the dehumidification operation and a cooling operation different from the dehumidification operation.
The air conditioner according to claim 1. The control unit is adapted to stop the compressor when a predetermined thermo-off condition is satisfied during the cooling operation,
The control unit has only the thermo-off temperature condition based on the indoor temperature as a determination element for determining whether the thermo-off condition is satisfied during the cooling operation.
The air conditioner according to claim 2. The control unit
determining that the condition of the thermo-off temperature is met when the indoor temperature has reached the thermo-off temperature or below continuously for a predetermined time during the dehumidifying operation;
When the room temperature reaches the thermo-off temperature or less during the cooling operation, it is determined that the thermo-off temperature condition is satisfied.
The air conditioner according to claim 3. The thermo-off temperature of the thermo-off temperature condition during the dehumidifying operation is lower than the thermo-off temperature of the thermo-off temperature condition during the cooling operation.
The air conditioner according to claim 3 or 4. The number of rotations of the indoor fan during the dehumidifying operation is limited to a number of rotations of the indoor fan that can be set during the cooling operation.
The air conditioner according to any one of claims 2-5. The number of rotations of the indoor fan during the dehumidifying operation is equal to or lower than the minimum number of rotations among the number of rotations that can be set during the cooling operation.
The air conditioner according to claim 6. The evaporation temperature during the dehumidifying operation is operated at or below the evaporation temperature during the cooling operation.
The air conditioner according to any one of claims 2-7. The control unit is configured to be able to select a plurality of dehumidification operation modes with different dehumidification levels as the dehumidification operation.
The air conditioner according to any one of claims 1 to 8. Evaporation temperature changes according to the dehumidification level of the selected dehumidification operation mode,
The air conditioner according to claim 9. Further comprising an indoor humidity sensor (35) for detecting the indoor humidity,
When the indoor humidity sensor is abnormal, the control unit performs the dehumidifying operation using a substitute value as the indoor humidity instead of the detected value of the indoor humidity sensor.
The air conditioner according to any one of claims 1 to 10. a refrigerant circuit (10) configured by connecting a compressor (21), an outdoor heat exchanger (24), an expansion mechanism (25), and an indoor heat exchanger (31);
an indoor fan (32) for sending indoor air to the indoor heat exchanger;
a control unit (6) for performing a dehumidification operation in which the refrigerant enclosed in the refrigerant circuit is circulated in the order of the compressor, the outdoor heat exchanger, the expansion mechanism, and the indoor heat exchanger;
and
The control unit selectively performs the dehumidification operation and the cooling operation different from the dehumidification operation,
The control unit performs thermo-off to stop the compressor when a predetermined thermo-off condition is satisfied during the dehumidifying operation,
The control unit has a thermo-off temperature condition based on room temperature and a thermo-off humidity condition based on room humidity as determination elements for determining whether the thermo-off condition is satisfied during the dehumidifying operation,
During the dehumidification operation, if the thermostat-off temperature condition is satisfied but the thermostat-off humidity condition is not satisfied, the control unit does not stop the compressor, and reduces the evaporation temperature of the refrigerant in the indoor heat exchanger. controls the capacity of the compressor and the air volume of the indoor fan so that is below the dew point temperature of the indoor air;
An air conditioner (1).

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