JP7041365B2 - Air conditioner - Google Patents

Description

The present disclosure relates to an air conditioner.

Patent Document 1 discloses an air conditioner having a function of suppressing the growth of mold and bacteria. As shown in FIG. 2 of the same document, in the air conditioner, a heating operation is executed after the dehumidifying operation is executed. In the dehumidifying operation, dew condensation water is generated on the surface of the indoor heat exchanger. In the heating operation, the indoor heat exchanger functions as a condenser and the indoor blower operates. The indoor heat exchanger is further dried by the refrigerant inside it.

Japanese Unexamined Patent Publication No. 2009-121789

In the air conditioner, is the outdoor unit (heat source unit) incapable of performing the first operation including the operation of causing dew condensation water or ice in the indoor heat exchanger (utilized heat exchanger)? Or, if the indoor unit (utilization unit) cannot perform the first operation, it cannot operate properly.

An object of the present disclosure is to appropriately perform a first operation in which the heat source unit and the utilization unit operate together.

The first aspect comprises a compressor (21), at least one heat source heat exchanger (22), a decompression mechanism (23) and at least one utilization heat exchanger (53), and a refrigerant circuit (11) performing a refrigeration cycle. ), At least one heat source unit (20) provided with the heat source heat exchanger (22), at least one utilization unit (40) provided with the utilization heat exchanger (53), and a first operation. The first operation includes a control device (C) that controls the heat source unit (20) and the utilization unit (40) so as to execute the first operation, and the first refrigeration using the utilization heat exchanger as an evaporator. It is an operation including a first operation of performing a cycle and causing dew condensation water or ice in the utilization heat exchanger (53), and in the control device (C), the heat source unit (20) executes the first operation. The first operation is restricted when the first heat source unit (20r) which cannot be performed is included, or when the utilization unit (40) includes the first utilization unit (40c, 40d) which cannot execute the first operation. , An air conditioner.

In the first aspect, the first operation is restricted when the heat source unit (20) includes the first heat source unit (20r) or when the utilization unit (40) includes the first utilization unit (40c, 40d). To. Therefore, when the air conditioner includes the first heat source unit (20r) or the first utilization unit (40c, 40d), it is possible to avoid a situation in which the air conditioner cannot operate properly in the first operation. As a result, the first operation in which the heat source unit (20) and the utilization unit (40) operate together can be appropriately executed.

In the second aspect, in the air conditioner of the first aspect, the utilization unit (40) is provided in plurality, and in the control device (C), the heat source unit (20) has the first heat source unit (20r). If included, or if the utilization unit (40) includes the first utilization unit (40c, 40d), the execution of the first operation in all the utilization units (40) and the heat source unit (20) is restricted. It is an air conditioner.

In the second aspect, as a limitation of the first operation, the execution of the first operation in all the utilization units (40) and the heat source unit (20) is restricted. Therefore, the relatively simple configuration and control of the air conditioner avoids the situation where the air conditioner cannot operate properly in the first operation.

A third aspect is in the air conditioner of the first or second aspect, the first operation includes a second operation performed after the first operation, and the second operation is the refrigerant circuit (11). ) Is an air conditioner that performs a second refrigeration cycle using the utilization heat exchanger (53) as a radiator and heats air by the utilization heat exchanger (53).

In the third aspect, in the first operation, the second operation is performed after the first operation. In the first operation, dew condensation water or ice is generated on the utilization heat exchanger (53). In the second operation, the used heat exchanger (53) is dried by the refrigerant of the used heat exchanger used as the radiator.

A fourth aspect is the air conditioner of the third aspect, wherein the utilization unit (40) has a blower (52) for transporting air passing through the utilization heat exchanger (53), and the utilization unit. As (40), the second utilization unit (40a, 40b) capable of executing the second operation of operating the blower (52) with the first operation and the heat exchange with the utilization heat exchanger (53) stopped. ) And the third utilization unit (40c) capable of executing the second operation, the first refrigeration cycle is performed, and the air is cooled by the utilization heat exchanger (53) to create a target space. It is an air conditioner that causes each of the second utilization unit (40a, 40b) and the third utilization unit (40c) to start the second operation when the cooling operation for air conditioning is completed.

In the fourth aspect, when the third utilization unit (40c) and the second utilization unit (40a, 40b) are provided as the utilization unit (40), the second operation is started when the cooling operation is completed. In the cooling operation, dew condensation water may occur in the heat exchanger (53) used. In the second operation, the used heat exchanger (53) is dried by the air carried by the blower (52). Therefore, even if the air conditioner includes the third utilization unit (40c) and the first operation is restricted and the second operation cannot be performed, the utilization heat exchanger (53) can be dried by the second operation.

A fifth aspect is the air conditioner of the fourth aspect, wherein the control device (C) is the second utilization unit (40a, 40b) and the third utilization unit (40c) as the utilization unit (40). ) And the fourth utilization unit (40d), which is the first utilization unit incapable of executing the second operation, the execution of the second operation in all the utilization units (40) is performed. A limiting, air conditioner.

In the fifth aspect, as the utilization unit (40), the second utilization unit (40a, 40b) and the fourth utilization unit (40d), the third utilization unit (40c) and the fourth utilization unit (40d), or the second utilization unit (40d). When the utilization unit (40a, 40b), the third utilization unit (40c), and the fourth utilization unit (40d) are provided, the execution of the second operation in all the utilization units (40) is restricted. In this case, the execution of the second operation in the plurality of utilization units (40) can be controlled in common.

A sixth aspect further comprises an operation unit (C3) that receives an operation for executing the first operation or the second operation in the air conditioner according to any one of the first to fifth aspects. The operation unit (C3) has a display unit (80) for displaying the setting items (120) related to the first operation and the second operation, and the utilization unit (40) is the utilization heat exchanger (53). The heat source unit (20) is a second heat source unit (20q) capable of performing the first operation, and the utilization unit (40) has a blower (52) for transporting air passing through the air. When the second utilization unit (40a, 40b) is capable of performing the second operation of operating the blower (52) with the first operation and the heat exchange of the utilization heat exchanger (53) stopped. As the setting item (120), the display unit (80) includes a first item (141) for executing the first operation and a second item (142) for executing the second operation. An air conditioner that can be displayed in a selectable manner.

In the sixth aspect, when the heat source unit (20) is the second heat source unit (20q) and the utilization unit (40) is the second utilization unit (40a, 40b), the display unit (80) The first item (141) for executing the first operation and the second item (142) for executing the second operation are displayed in a selectable manner. In this case, by operating the operation unit (C3) to select either the first item (141) or the second item (142), the first operation or the second operation is executed according to the selected item. Can be made to.

A seventh aspect further comprises an operation unit (C3) that receives an operation for executing the first operation or the second operation in the air conditioner according to any one of the fourth to sixth aspects. The operation unit (C3) has a display unit (80) that displays setting items (120) related to the first operation and the second operation, and can execute the second operation as the utilization unit (40). When the third utilization unit (40c) which is the first utilization unit (40c, 40d) and the second utilization unit (40a, 40b) are provided, the display unit (80) is the setting item (120). ), Which is an air conditioner that does not display the first item (141) for executing the first operation, or displays it in a non-selectable manner.

In the seventh aspect, when the second utilization unit (40a, 40b) and the third utilization unit (40c) are provided as the utilization unit (40), the display unit (80) is used to execute the first operation. The first item (141) is not displayed or is displayed as non-selectable. As a result, the operation unit (C3) cannot select the first item (141), and the execution of the first operation can be restricted.

The eighth aspect further comprises an operation unit (C3) for receiving an operation for executing the first operation or the second operation in the air conditioner according to any one of the fourth to seventh aspects. The operation unit (C3) has a display unit (80) that displays setting items (120) related to the first operation and the second operation, and can execute the second operation as the utilization unit (40). At least one of the third utilization unit (40c) which is the first utilization unit (40c, 40d) and the second utilization unit (40a, 40b), and the first utilization unit (which cannot execute the second operation). The display unit (80) is an air conditioner that does not display the setting item (120) or displays it in a non-selectable manner when the fourth utilization unit (40d) which is 40c, 40d) is provided. ..

In the eighth aspect, the utilization unit (40) is the third utilization unit (30c) and the fourth utilization unit (40d), the second utilization unit (40a, 40b) and the fourth utilization unit (40d), or the second utilization. When the unit (40a, 40b), the third utilization unit (40c), and the fourth utilization unit (40d) are provided, the setting item (120) relating to the first operation and the second operation is displayed on the display unit (80). Not displayed or displayed as non-selectable. As a result, the operation unit (C3) cannot operate the setting item (120), and the execution of the first operation and the second operation can be restricted.

A ninth aspect is that in any one of the first to eighth aspects of the air conditioner, the refrigerant circuit (11), the at least one heat source unit (20) and the at least one utilization unit (40) One air-conditioning unit (15) is configured, and a plurality of the air-conditioning units (15) are provided. In the control device (C3), the heat source unit (20) is the first in each of the plurality of the air-conditioning units (15). When the heat source unit (20r) is included, or when the utilization unit (40) includes the first utilization unit (40c, 40d), the first heat source unit (20r) or the first utilization unit (40c, 40d) is included. ) Is an air conditioner that limits the execution of the first operation of the air conditioning unit (15).

In the ninth aspect, the execution of the first operation of the air conditioning unit (15) having the first heat source unit (20r) or the first utilization unit (40c, 40d) is restricted. As a result, in the air conditioner including the plurality of air conditioning units (15), the first operation can be appropriately executed for each air conditioning unit (15), avoiding the situation where the first operation cannot be properly operated.

A tenth aspect is in the air conditioner according to any one of the fourth to eighth aspects, wherein the refrigerant circuit (11), at least one heat source unit (20), and at least one utilization unit (40) are used. An operation unit (which constitutes one air conditioning unit (15), includes a plurality of the air conditioning units (15), and receives an operation for causing the plurality of the air conditioning units (15) to execute the first operation or the second operation. Further comprising C3), the operation unit (C3) has a display unit (80) for displaying setting items (120) relating to the first operation and the second operation, and at least one air conditioning unit (15). Is the first air conditioning unit (15x) that is allowed to execute the first operation, the display unit (80) has the first item (141) for executing the first operation as the setting item. ) And the second item (142) for executing the second operation are selectively displayed.

In the tenth aspect, when at least one air conditioning unit (15) is the first air conditioning unit (15x), the display unit (80) has the first item (141) for executing the first operation. The second item (142) for executing the second operation is displayed in a selectable manner. In this case, by operating the operation unit (C3) to select one of the first item (141) and the second item (142), the first air conditioning unit (15x) can be selected according to the selected item. One operation or a second operation can be executed.

The eleventh aspect further comprises an operation unit (C3) for receiving an operation for executing the first operation in the air conditioner according to any one of the first to tenth aspects, and the operation unit (C3). Is information that can identify whether or not the heat source unit (20) is the first heat source unit (20r), and / or the utilization unit (40) is the first utilization unit (40c, 40d). It is an air conditioner having a display unit (80) that displays information that can identify whether or not the air conditioner is present.

In the eleventh aspect, in the display unit (80), whether or not the heat source unit (20) is the first heat source unit (20r) and whether the utilization unit (40) is the first utilization unit (40c, 40d). Information that can identify both or not information is displayed. Thereby, when the air conditioner includes the first heat source unit (20r) or the first utilization unit (40c, 40d), the presence of the first heat source unit (20r) or the first utilization unit (40c, 40d) is displayed. It can be confirmed in the part (80).

FIG. 1 is an overall configuration diagram of an air conditioner according to the first embodiment. FIG. 2 is a piping system diagram of the air conditioner according to the first embodiment. FIG. 3 is a block diagram showing a control device and a device connected to the control device via a communication line. FIG. 4 is a time chart diagram showing the operation of each device in the normal operation and the first operation. FIG. 5 is a time chart diagram showing the operation of each device in the normal operation and the second operation. FIG. 6 is a diagram showing an example of a third menu screen displayed on the display unit of the remote controller. FIG. 7 is a diagram showing an example of a first menu screen displayed on the display unit of the remote controller. FIG. 8 is a diagram showing an example of a second menu screen displayed on the display unit of the remote controller. FIG. 9 is a diagram showing an example of a screen for switching between enabling and disabling the first mode on the display unit of the remote controller. FIG. 10 is a diagram showing an example of a screen for setting the type of the first mode on the display unit of the remote controller. FIG. 11 is a diagram showing the display contents of the remote controller of the air conditioner according to the first embodiment. FIG. 12 is a diagram showing the operation contents of the indoor unit which is the master unit based on the instruction signal of the remote controller. FIG. 13 is a diagram showing the operation contents of the indoor unit, which is a slave unit, based on the instruction signal of the indoor unit, which is the master unit. FIG. 14 is a schematic configuration diagram showing an example of an air conditioning unit of a type in which execution of the first operation and the second operation is permitted. FIG. 15 is a schematic configuration diagram showing an example of a type of air conditioning unit in which the execution of the second operation is restricted and the execution of the first operation is permitted. FIG. 16 is a schematic configuration diagram showing an example of a type of air conditioning unit in which the execution of the first operation is restricted and the execution of the second operation is permitted. FIG. 17 is a schematic configuration diagram showing an example of a type of air conditioning unit in which the execution of the first operation is restricted and the execution of the second operation is permitted. FIG. 18 is a schematic configuration diagram showing an example of a type of air conditioning unit in which the execution of the first operation is restricted and the execution of the second operation is permitted. FIG. 19 is a schematic configuration diagram showing an example of a type of air conditioning unit whose execution of the first operation and the second operation is restricted. FIG. 20 is a schematic configuration diagram showing an example of a type of air conditioning unit whose execution of the first operation and the second operation is restricted. FIG. 21 is an overall configuration diagram of the air conditioner according to the second embodiment. FIG. 22 is a diagram showing the display contents of the remote controller of the air conditioner according to the second embodiment. FIG. 23 is a diagram showing the operation contents of the indoor unit based on the instruction signal of the remote controller. FIG. 24 is a schematic configuration diagram showing an example of an air conditioner that is allowed to perform the first operation and the second operation. FIG. 25 is a schematic configuration diagram showing an example of an air conditioner in which the execution of either the first operation or the second operation is permitted and the execution of the other is restricted. FIG. 26 is a schematic configuration diagram showing an example of an air conditioner whose execution of the first operation and the second operation is restricted.

Hereinafter, embodiments of the present disclosure will be described with reference to the drawings. It should be noted that the following embodiments are essentially preferred examples and are not intended to limit the scope of the techniques, applications thereof, or uses thereof of the present disclosure.

<< Embodiment 1 >>
In the first embodiment, the technique of the present disclosure will be described by exemplifying a multi-type air conditioner having a single refrigerant system.

<Overall configuration of air conditioner>
The air conditioner (10) regulates the temperature of the air in the target space. The target space of this example is an indoor space. As shown in FIGS. 1 and 2, the air conditioner (10) of the first embodiment includes one outdoor unit (20), a plurality of indoor units (40), a liquid communication pipe (12), and a gas. It is equipped with a connecting pipe (13).

Each of the plurality of indoor units (40) and the outdoor unit (20) are connected to each other via a liquid connecting pipe (12) and a gas connecting pipe (13). By connecting these, the refrigerant circuit (11) is configured. The refrigerant circuit (11) is filled with the refrigerant. The refrigerant in this example is difluoromethane. The refrigerant circuit (11) performs a steam compression type refrigeration cycle. The refrigerant circuit (11) mainly has a compressor (21), an outdoor heat exchanger (22), an expansion valve (23), an indoor heat exchanger (53), and a four-way switching valve (25). .. The refrigerant circuit (11), the outdoor unit (20) and the plurality of indoor units (40) constitute one air conditioning unit (15).

<Outdoor unit>
The outdoor unit (20) is installed outdoors. As shown in FIG. 2, the outdoor unit (20) has a compressor (21), an outdoor heat exchanger (22), an expansion valve (23), a four-way switching valve (53) and an outdoor fan (26).

The compressor (21) sucks in a low-pressure gas refrigerant and compresses it. The compressor (21) discharges the compressed refrigerant. The compressor (21) is a variable capacitance type in which electric power is supplied from an inverter circuit to an electric motor. In other words, the compressor (21) is configured so that the operating frequency (rotational speed) of the electric motor can be adjusted.

The outdoor heat exchanger (22) is an example of a heat source heat exchanger. The outdoor heat exchanger (22) is provided in the outdoor unit (20). The outdoor fan (26) carries the outdoor air passing through the outdoor heat exchanger (22). The outdoor heat exchanger (22) exchanges heat between the outdoor air carried by the outdoor fan (26) and the refrigerant.

The expansion valve (23) is an example of a pressure reducing mechanism. The expansion valve (23) depressurizes the refrigerant. The expansion valve (23) is an electric expansion valve whose opening degree can be adjusted. The depressurizing mechanism may be a temperature-sensitive expansion valve, an expander, a capillary tube, or the like. The expansion valve (23) may be connected to the liquid line of the refrigerant circuit (11) and may be provided in the indoor unit (40).

The four-way switching valve (25) has a first port (P1), a second port (P2), a third port (P3), and a fourth port (P4). The first port (P1) is connected to the discharge portion of the compressor (21). The second port (P2) is connected to the suction part of the compressor (21). The third port (P3) is connected to the gas end of the outdoor heat exchanger (22). The fourth port (P4) is connected to the gas connecting pipe (13).

The four-way switching valve (25) switches between the first state (the state shown by the solid line in FIG. 2) and the second state (the state shown by the broken line in FIG. 2). The four-way switching valve (25) in the first state communicates the first port (P1) and the third port (P3), and communicates the second port (P2) and the fourth port (P4). The four-way switching valve (25) in the second state communicates the first port (P1) and the fourth port (P4), and communicates the second port (P2) and the third port (P3).

The refrigerant circuit (11) performs a first refrigeration cycle and a second refrigeration cycle according to the switching of the four-way switching valve (25). The first refrigeration cycle is a refrigeration cycle in which each indoor heat exchanger (53) is used as an evaporator. The second refrigeration cycle is a refrigeration cycle using the indoor heat exchanger (53) as a radiator.

The outdoor unit (20) has a discharge pressure sensor (27), a discharge temperature sensor (28), a suction temperature sensor (29), an outside air temperature sensor (30), and a first refrigerant temperature sensor (31).

The discharge pressure sensor (27) detects the pressure of the high-pressure refrigerant discharged from the compressor (21). The suction temperature sensor (29) detects the pressure of the low pressure refrigerant sucked into the compressor (21). The outside air temperature sensor (30) detects the temperature of the outdoor air. The first refrigerant temperature sensor (31) detects the temperature of the refrigerant inside the outdoor heat exchanger (22).

<Indoor unit>
Each of the plurality of indoor units (40) is installed indoors. The plurality of indoor units (40) target the same indoor space as the target space. The plurality of indoor units (40) may have different indoor spaces as target spaces. Each indoor unit (40) is a ceiling-suspended type that is suspended from a beam behind the ceiling.

Each indoor unit (40) has an indoor fan (52), an indoor heat exchanger (53), a drain pan (not shown) and a drain pump (58).

The indoor fan (52) is an example of a blower. The indoor fan (52) is a centrifugal type. The indoor fan (52) carries air passing through the indoor heat exchanger (53). The indoor fan (52) is configured so that its air volume can be switched in stages. For example, the switchable air volume of the indoor fan (52) has four stages, and is, in order from the smallest air volume, the light air volume (LL), the small air volume (L), the medium air volume (M), and the large air volume (H).

The indoor heat exchanger (53) is an example of a utilization heat exchanger. The indoor heat exchanger (53) is provided in the indoor unit (40). The indoor heat exchanger (53) is arranged around the indoor fan (52). The indoor heat exchanger (53) exchanges heat between the air carried by the indoor fan (52) and the refrigerant.

The drain pan is located below the indoor heat exchanger (53). The drain pan receives the dew condensation water generated inside the indoor unit (40).

The drain pump (58) is a pump that discharges the water in the drain pan. The drain pump (58) discharges the water in the drain pan to the outside of the casing (41) of the indoor unit (40) via the drainage channel.

The indoor unit (40) has an inside air temperature sensor (61), an inside air humidity sensor (62), and a second refrigerant temperature sensor (63).

The inside air temperature sensor (61) detects the temperature of the indoor air in the target space as the indoor temperature (T1). The room temperature (T1) is the temperature of the sucked air.

The inside air humidity sensor (62) detects the humidity of the indoor air in the target space as the indoor humidity (R1). The indoor humidity (R1) is the humidity of the sucked air. The second refrigerant temperature sensor (63) detects the temperature of the refrigerant in the indoor heat exchanger (53).

The second refrigerant temperature sensor (63) detects the evaporation temperature (Te) of the indoor heat exchanger (53) that functions as an evaporator. The second refrigerant temperature sensor (63) detects the condensation temperature (Tc) of the indoor heat exchanger (53), which functions as a radiator (strictly speaking, a condenser).

The second refrigerant temperature sensor (63) also serves as a sensor for detecting the in-flight temperature (T2) of the indoor unit (40). The in-flight temperature (T2) corresponds to the temperature inside the indoor unit (40). The air conditioner (10) may have another sensor for detecting the in-flight temperature (T2) in addition to the second refrigerant temperature sensor (63).

The plurality of indoor units (40) are divided into a master unit (40M) and a slave unit (40S). One indoor unit (40) is set to the master unit (40M). The remaining indoor unit (40) is set to the slave unit (40S). The indoor unit (40M) set in the master unit comprehensively controls the operation of the indoor unit (40S) set in the slave unit and the operation of the outdoor unit (20).

<Control device>
As shown in FIG. 3, the air conditioner (10) has a control device (C). The control device (C) controls the refrigerant circuit (11). The control device (C) controls the outdoor unit (20) and each indoor unit (40). The control device (C) includes an outdoor control unit (C1), an indoor control unit (C2), and a remote controller (C3). The outdoor control unit (C1) is provided in the outdoor unit (20). The indoor control unit (C2) is provided in each of the plurality of indoor units (40).

The control device (C) has a plurality of first communication lines. The first communication line is wired. The outdoor control unit (C1) has at least sensors for the compressor (21), expansion valve (23), four-way switching valve (25), outdoor fan (26), and outdoor unit (20) via the first communication line. Is connected to. The indoor control unit (C2) is connected to at least the sensors of the indoor fan (52), the drain pump (58) and the indoor unit (40) via the first communication line.

The outdoor control unit (C1) and the indoor control unit (C2) each have a control board. Each control board of the outdoor control unit (C1) and the indoor control unit (C2) is provided with a communication unit (14), a CPU (15), and a memory (16).

The communication unit (14) is an interface for communicating with other devices. The control device (C) has a plurality of second communication lines (L2). The communication unit (14M) of the indoor unit (40M), which is the master unit, and the communication unit (14) of the outdoor unit (20) are communicably connected via the second communication line (L2). The communication unit (14) of the indoor unit (40M), which is the master unit, and the communication unit (14) of the indoor unit (14S), which is the slave unit, are connected so as to be communicable via the second communication line (L2). To. The second communication line (L2) is wired. The second communication line (L2) may be wireless.

The communication unit (14) of the indoor unit (40M), which is the master unit, is the communication unit (14) of the indoor unit (40S), which is the slave unit, and the communication unit (14) of the outdoor unit (20), and the second communication line ( Send and receive signals via L2). Each communication unit (14) of the outdoor control unit (C1) and the indoor control unit (C2) has a transmission unit (17) and a reception unit (18) as functional units. The transmission unit (17) transmits various signals to other devices. The receiving unit (18) receives a signal transmitted from another device.

The CPU (15) performs various processes based on the software in the memory (16). The CPU (15) identifies the signal received by the receiving unit (18), and performs processing according to the signal. The CPU (15) of the outdoor control unit (C1) sends control signals for executing and stopping the operation of the outdoor unit (20) to the compressor (21), the expansion valve (23), the four-way switching valve (25), and the four-way switching valve (25). Output to the outdoor fan (26). The CPU (15) of the indoor control unit (C2) outputs a control signal for executing and stopping the operation of the indoor unit (40) to the indoor fan (52) and the drain pump (58).

The memory (16) stores various software and data for operating the CPU (15). The memory (16) stores software and data for identifying the signal received by the receiving unit (18). The data based on the signal received by the receiving unit (18) is stored in the memory (16). The memory (16) stores a serial number unique to the control board, model information, an address set for communication, and the like. The detected value of each sensor is input to the outdoor control unit (C1) or the indoor control unit (C2) and stored in the memory (16). The memory (16) is composed of, for example, a RAM (Random Access Memory), a ROM (Read Only Memory), or the like.

The remote controller (C3) is placed in a position where the user can operate it. The remote controller (C3) has a display unit (80), an input unit (81), and a control board. A communication unit (82), a CPU (83), and a memory (84) are provided on the control board of the remote controller (C3).

The display unit (80) displays a sign for notifying a user, a maintenance company, or the like of predetermined information. The sign here includes characters, codes, symbols, pictures, icons and the like. The display unit (80) is configured by, for example, a liquid crystal monitor. The predetermined information is information indicating the operating state and the set temperature of the air conditioner (10).

The input unit (81) accepts an input operation for making various settings from the user. The input unit (81) is composed of a touch panel and / or a physical switch.

The communication unit (82) is an interface for communicating with the air conditioning unit (15). The control device (C) has a third communication line (L3). The communication unit (82) is communicably connected to the communication unit (14M) of the indoor unit (40M), which is the master unit, via the third communication line (L3). The third communication line (L3) is wired. The third communication line (L3) may be wireless. The communication unit (82) of the remote controller (C3) sends and receives signals via the communication unit (14) of the indoor unit (40M), which is the master unit, and the third communication line (L3). The communication unit (82) has a transmission unit (85) and a reception unit (86) as functional units. The transmission unit (85) transmits various signals to the indoor unit (40M), which is the master unit. The receiving unit (86) receives the signal transmitted from the indoor unit (40M) which is the master unit.

The CPU (83) performs various processes based on the software and data in the memory (84). The CPU (83) causes the transmission unit (85) to transmit an instruction signal to the indoor unit (40M), which is the master unit, in response to a user operation on the input unit (81). The CPU (83) identifies the signal received by the receiving unit (86), and performs processing according to the signal. The CPU (83) switches the display content of the menu screen (100) displayed on the display unit (80).

The memory (84) stores various programs and data for operating the CPU (83). The memory (84) stores a program and data for identifying a signal received by the receiving unit (86). The data based on the signal received by the receiving unit (83) is stored in the memory (84). The memory (84) stores a program and data for receiving an input operation in the input unit (81). Various settings made by the input operation in the input unit (81) are stored in the memory (84). The memory (84) is composed of, for example, a RAM (Random Access Memory), a ROM (Read Only Memory), or the like.

In the control device (C), the instruction signal instructing the operation of the air conditioner (10) from the remote controller (C3) is transmitted by the transmission unit (85) to the indoor control unit (40M) of the indoor unit (40M) which is the master unit. It will be sent to C2). When the indoor control unit (C2) of the indoor unit (40M), which is the master unit, receives the instruction signal from the remote controller (C3) by the reception unit (18), the instruction signal is transmitted by the operation of the CPU (15). The signal is transmitted from the unit (17) to the indoor control unit (C2) and the outdoor control unit (C1) of the indoor unit (40S) which is a slave unit.

When the indoor control unit (C2) of the indoor unit (40M), which is the master unit, receives the instruction signal from the remote controller (C3) by the receiving unit (18), the indoor control unit (15) identifies the instruction signal by the operation of the CPU (15). The indoor control unit (C2) of the indoor unit (40M), which is the master unit, controls the indoor fan (52), the drain pump (58), and the like by the operation of the CPU (15) according to the content of the instruction signal.

When the indoor control unit (C2) of the indoor unit (40S), which is a slave unit, receives an instruction signal from the indoor control unit (C2) of the indoor unit (40M), which is a master unit, the indoor control unit (C2) is instructed by the operation of the CPU (15). Identify the signal. The indoor control unit (C2) of the indoor unit (40S), which is a slave unit, controls the indoor fan (52), the drain pump (58), and the like by the operation of the CPU (15) according to the content of the instruction signal.

When the outdoor control unit (C1) receives the instruction signal from the indoor control unit (C2) of the indoor unit (40M) which is the master unit, the outdoor control unit (C1) identifies the instruction signal by the operation of the CPU (15). The outdoor control unit (C1) operates the compressor (21), the outdoor heat exchanger (22), the expansion valve (23), the four-way switching valve (53) and the outdoor by the operation of the CPU (15) according to the content of the instruction signal. Control the fan (26).

-Driving operation-
<Normal operation>
The air conditioner (10) operates normally. Normal operation is operation that air-conditions the target space. Normal operation includes cooling operation, heating operation and dehumidifying operation.

The cooling operation is an operation of cooling the air in the target space. The dehumidifying operation is an operation of dehumidifying the air in the target space. The cooling operation and the dehumidifying operation correspond to the cooling operation. The cooling operation is an operation in which the first refrigeration cycle is performed and the air is cooled by the indoor heat exchanger (53) used as an evaporator. The heating operation is an operation of heating the air in the target space. The heating operation is an operation in which the second refrigeration cycle is performed and the air is heated by the indoor heat exchanger (53) used as a radiator.

<Cooling operation>
In the cooling operation, the control device (C) operates the compressor (21), the indoor fan (52), and the outdoor fan (26). The control device (C) sets the four-way switching valve (25) to the first state. The control device (C) appropriately adjusts the opening degree of the expansion valve (23). In the cooling operation, the first refrigeration cycle is performed in which the refrigerant compressed by the compressor (21) dissipates heat in the outdoor heat exchanger (22) and evaporates in the indoor heat exchanger (53).

In the cooling operation, the refrigerant compressed by the compressor (21) passes through the four-way switching valve (25) and flows through the outdoor heat exchanger (22). In the outdoor heat exchanger (22), the refrigerant dissipates heat to the outdoor air and condenses. The refrigerant radiated by the outdoor heat exchanger (22) is decompressed by the expansion valve (23) and then flows through the indoor heat exchanger (53). In the indoor heat exchanger (53), the refrigerant absorbs heat from the indoor air and evaporates. The air cooled by the indoor heat exchanger (53) is supplied to the target space from the outlet (47) of the indoor unit (40). The refrigerant evaporated in the indoor heat exchanger (53) is sucked into the compressor (21) and compressed again.

In the cooling operation, the control device (C) adjusts the target evaporation temperature (TeS) of the indoor heat exchanger (53) so that the indoor temperature (T1) converges to the set temperature. The control device (C) controls the rotation speed of the compressor (21) so that the evaporation temperature (Te) of the refrigerant of the indoor heat exchanger (53) converges to the target evaporation temperature (TeS).

<Dehumidifying operation>
In the dehumidifying operation, the control device (C) operates the compressor (21), the indoor fan (52), and the outdoor fan (26). The control device (C) sets the four-way switching valve (25) to the first state. The control device (C) appropriately adjusts the opening degree of the expansion valve (23). In the dehumidifying operation, the first refrigeration cycle is performed in which the refrigerant compressed by the compressor (21) dissipates heat in the outdoor heat exchanger (22) and evaporates in the indoor heat exchanger (53). The flow of the refrigerant in the dehumidifying operation is the same as the flow of the refrigerant in the cooling operation.

In the dehumidifying operation, the control device (C) controls the cooling capacity of the indoor heat exchanger (53) so that the evaporation temperature (Te) of the indoor heat exchanger (53) is lower than the dew point temperature (Td) of the indoor air. .. The control device (C) obtains the dew point temperature (Td) based on the room temperature (T1) detected by the inside air temperature sensor (61) and the room humidity (R1) detected by the inside air humidity sensor (62). The control device (C) adjusts the target evaporation temperature (TeS) so that the evaporation temperature (Te) of the indoor heat exchanger (53) is equal to or lower than the dew point temperature (Td). The control device (C) controls the rotation speed of the compressor (21) so that the evaporation temperature (Te) of the refrigerant of the indoor heat exchanger (53) converges to the target evaporation temperature (TeS).

With the above control, in the dehumidifying operation, the moisture in the indoor air cooled by the indoor heat exchanger (53) is dewed. This dehumidifies the indoor air. The drain pan receives the water that has condensed. The dehumidified air is supplied to the target space from the outlet (47) of the indoor unit (40).

<Heating operation>
In the heating operation, the control device (C) operates the compressor (21), the indoor fan (52), and the outdoor fan (26). The control device (C) sets the four-way switching valve (25) to the second state. The control device (C) appropriately adjusts the opening degree of the expansion valve (23). In the heating operation, a second refrigeration cycle is performed in which the refrigerant compressed by the compressor (21) dissipates heat in the indoor heat exchanger (53) and evaporates in the outdoor heat exchanger (22).

In the heating operation, the refrigerant compressed by the compressor (21) passes through the four-way switching valve (25) and flows through the indoor heat exchanger (53). In the indoor heat exchanger (53), the refrigerant dissipates heat to the indoor air and condenses. The air heated by the indoor heat exchanger (53) is supplied to the target space from the outlet (47) of the indoor unit (40). The refrigerant radiated by the indoor heat exchanger (53) is decompressed by the expansion valve (23) and then flows through the outdoor heat exchanger (22). In the outdoor heat exchanger (22), the refrigerant absorbs heat from the outdoor air and evaporates. The refrigerant evaporated in the outdoor heat exchanger (22) is sucked into the compressor (21) and compressed again.

In the heating operation, the control device (C) adjusts the target condensation temperature (TcS) of the indoor heat exchanger (53) so that the indoor temperature (T1) converges to the set temperature. The control device (C) controls the rotation speed of the compressor (21) so that the condensation temperature (Tc) of the refrigerant in the indoor heat exchanger (53) converges to the target condensation temperature (TcS).

<First mode>
The air conditioner (10) can perform the first mode depending on the model of the outdoor unit (20) and the model of the indoor unit (40).

As the first mode, there are a first operation and a second operation. The first operation is an operation of cleaning the indoor heat exchanger (53) of each indoor unit (40). The second operation is an operation of drying the indoor heat exchanger (53) of each indoor unit (40).

<First operation>
Depending on the model of the outdoor unit (20) and the model of each indoor unit (40), the control device (C) may perform the first operation when the normal operation ends when the automatic execution of the first mode is enabled. To execute. Strictly speaking, the control device (C) starts the first operation when the cooling operation and the dehumidifying operation are completed. The control device (C) does not start the first operation even after the heating operation is completed.

In the first operation, the first operation, the third operation, the second operation, and the fourth operation are executed in order.

The execution time of the first operation is ΔT1, the execution time of the third operation is ΔT3, the execution time of the second operation is ΔT2, and the execution time of the fourth operation is ΔT4. As a general rule, the execution time ΔT3 of the third operation is longer than the execution time ΔT2 of the second operation. The execution time ΔT3 of the third operation is longer than the execution time ΔT1 of the first operation. The execution time ΔT3 of the third operation is longer than the execution time ΔT4 of the fourth operation.

The details of the first operation, the third operation, the second operation, and the fourth operation will be described with reference to FIG.

<First operation>
The first operation is an operation of removing dirt such as dust adhering to the surface of the indoor heat exchanger (53). The execution time ΔT1 of the first operation is 10 minutes in principle.

In the first operation, the control device (C) operates the compressor (21), the indoor fan (52) and the outdoor fan (26). The control device (C) sets the four-way switching valve (25) to the first state. The control device (C) appropriately adjusts the opening degree of the expansion valve (23). In the first operation, the refrigerant compressed by the compressor (21) dissipates heat in the outdoor heat exchanger (22), is depressurized by the expansion valve (23), and evaporates in the indoor heat exchanger (53). Will be done.

In the first operation, the control device (C) adjusts the target evaporation temperature (TeS) so that the evaporation temperature (Te) of the indoor heat exchanger (53) becomes equal to or lower than the dew point temperature (Td) of the indoor air. When the first operation is executed after the end of the cooling operation, the target evaporation temperature (TeS) at the time of the first operation is set to a value lower than the target evaporation temperature (TeS) at the end of the cooling operation. When the first operation is executed after the dehumidification operation is completed, the target evaporation temperature (TeS) at the end of the first operation is set to the same value as the target evaporation temperature (TeS) at the end of the dehumidification operation.

In the first operation, the air sucked from the suction port (46) of the indoor unit (40) passes through the indoor heat exchanger (53). In the indoor heat exchanger (53), the refrigerant cools the air to below the dew point temperature. As a result, dew condensation water is generated on the surface of the indoor heat exchanger (53). Condensed water removes dirt such as dust on the surface of the indoor heat exchanger (53). The dew condensation water used for cleaning the indoor heat exchanger (53) collects in the drain pan. The air that has passed through the indoor heat exchanger (53) flows out to the target space from the outlet (47) of the indoor unit (40).

In the first operation, the control device (C) controls the air volume of the indoor fan (52) to a light air volume (LL). As a result, the flow rate of air passing through the indoor heat exchanger (53) is reduced, and the amount of dew condensation water generated is increased. In addition, since the air volume of the blown air becomes small, it is possible to prevent people in the target space from feeling uncomfortable due to cold air.

In the first operation, the control device (C) operates the drain pump (58). As a result, the water accumulated in the drain pan can be discharged to the outside of the casing (41) of the indoor unit (40).

The evaporation temperature range of the indoor heat exchanger (53) during the first operation is lower than the evaporation temperature range of the evaporation temperature of the indoor heat exchanger (53) during the cooling operation. Specifically, the control range of the evaporation temperature of the indoor heat exchanger (53) during the first operation is lower than the control range of the evaporation temperature of the indoor heat exchanger (53) during the cooling operation. For example, the control range of the evaporation temperature in the cooling operation is 10 ° C to 30 ° C, and the control range of the evaporation temperature in the first operation is 4 ° C to 30 ° C. As described above, in the present embodiment, the upper limit value of the evaporation temperature range of the first operation (hereinafter referred to as the first evaporation temperature range) and the upper limit value of the evaporation temperature range of the cooling operation (hereinafter referred to as the second evaporation temperature range). Is the same, and the lower limit of the first evaporation temperature range is lower than the lower limit of the second evaporation temperature range.

The first evaporation temperature range and the second evaporation temperature range do not have to overlap at all. In this case, the upper limit of the first evaporation temperature range is lower than the lower limit of the second evaporation temperature. When a part of the first evaporation temperature range and the second evaporation temperature range overlap, the lower limit value of the first evaporation temperature range is lower than the lower limit value of the second evaporation temperature range, and the upper limit value of the first evaporation temperature range. May be lower than the upper limit of the second evaporation temperature range.

<Third operation>
The third operation is an operation of drying the water on the surface of the indoor heat exchanger (53) with the air carried by the indoor fan (52). By drying the water on the surface of the indoor heat exchanger (53), the growth of mold and bacteria on the surface of the indoor heat exchanger (53) can be suppressed. The execution time ΔT3 of the third operation is 100 minutes in principle.

In the third operation, the control device (C) stops the compressor (21) and the outdoor fan (26). The control device (C) operates the indoor fan (52). In the third operation, the first refrigeration cycle and the second refrigeration cycle are not performed, and the refrigerant does not flow through the indoor heat exchanger (53). Therefore, the indoor heat exchanger (53) is stopped. The term "indoor heat exchanger stops" as used herein means that the indoor heat exchanger (53) does not function as a radiator and an evaporator (the same applies hereinafter).

In the third operation, the air sucked from the suction port (46) of the indoor unit (40) passes through the indoor heat exchanger (53) in the stopped state. As a result, the water on the surface of the indoor heat exchanger (53) evaporates. The air used for drying the indoor heat exchanger (53) flows out to the target space from the outlet (47) of the indoor unit (40).

The execution time ΔT3 of the third operation is longer than the execution time ΔT2 of the second operation. Therefore, the water on the surface of the indoor heat exchanger (53) can be slowly dried over time. In the third operation, the indoor heat exchanger (53) does not become a radiator and is in a stopped state. Therefore, a large amount of water does not evaporate from the surface of the indoor heat exchanger (53). Therefore, it is possible to suppress the person in the target space from feeling uncomfortable due to the high temperature and high humidity air being supplied to the target space for a long period of time.

In the third operation, the control device (C) controls the air volume of the indoor fan (52) to a small air volume (L). This makes it possible to accelerate the drying of the indoor heat exchanger (53) as compared with the case where the air volume is a breeze volume (LL). Compared with the case where the air volume is medium air volume (M) or large air volume (H), it is possible to suppress the feeling of discomfort to the person in the target space.

In the third operation, the control device (C) operates the drain pump (58). Strictly speaking, the control device (C) continuously operates the drain pump (58) from the first operation to the third operation. As a result, the water remaining in the drain pan can be discharged to the outside of the casing (41) of the indoor unit (40).

<Second operation>
The second operation is an operation of heating the surface of the indoor heat exchanger (53) by flowing a refrigerant through the heat transfer tube of the indoor heat exchanger and drying the surface. By drying the water on the surface of the indoor heat exchanger (53), the growth of mold and bacteria on the surface of the indoor heat exchanger (53) can be suppressed. A bactericidal effect can also be obtained by raising the surface temperature of the indoor heat exchanger (53) to a high temperature. The execution time ΔT2 of the second operation is, in principle, 10 to 15 minutes.

In the second operation, the control device (C) operates the compressor (21), the indoor fan (52) and the outdoor fan (26). The control device (C) sets the four-way switching valve (25) to the second state. The control device (C) appropriately adjusts the opening degree of the expansion valve (23). In the second operation, the refrigerant compressed by the compressor (21) dissipates heat in the indoor heat exchanger (53), is depressurized by the expansion valve (23), and evaporates in the outdoor heat exchanger (22). Will be done.

In the second operation, the control device (C) adjusts the target condensation temperature (TcS) to a predetermined value.

In the second operation, the air sucked from the suction port (46) of the indoor unit (40) passes through the indoor heat exchanger (53). In the indoor heat exchanger (53), the surface of the indoor heat exchanger (53) is heated by the internal refrigerant. As a result, the water on the surface of the indoor heat exchanger (53) further evaporates. The air containing the evaporated water flows out to the target space from the outlet (47) of the indoor unit (40).

The execution time ΔT2 of the second operation is shorter than the execution time ΔT3 of the third operation. Therefore, it is possible to prevent people in the target space from feeling uncomfortable due to the supply of high temperature and high humidity air to the target space.

In the second operation, the heat of the refrigerant is used to dry the indoor heat exchanger (53). Therefore, even if the execution time ΔT2 is relatively short, the water content of the indoor heat exchanger (53) can be removed. As a result, the subsequent growth of mold and fungi can be suppressed.

In the second operation, the control device (C) controls the air volume of the indoor fan (52) to a small air volume (L). As a result, the air volume of the blown air is relatively small, so that it is possible to prevent people in the target space from feeling uncomfortable due to the high temperature and high humidity wind.

In the second operation, the control device (C) operates the drain pump (58). Strictly speaking, the control device (C) continuously operates the drain pump (58) from the third operation to the second operation. In other words, the control device (C) operates the drain pump (58) from the first operation to the second operation. As a result, the water remaining in the drain pan can be discharged to the outside of the casing (41) of the indoor unit (40).

<Fourth operation>
In the fourth operation, the control device (C) stops the compressor (21), the indoor fan (52), and the outdoor fan (26). In the fourth operation, the indoor unit (40) is substantially stopped.

In the fourth operation, the control device (C) operates the drain pump (58). Strictly speaking, the control device (C) continuously operates the drain pump (58) from the second operation to the fourth operation. In other words, the control device (C) operates the drain pump (58) from the first operation to the fourth operation. As a result, the water remaining in the drain pan can be discharged to the outside of the casing (41) of the indoor unit (40). In addition, it is possible to suppress the backflow of water into the drain pan, and it is possible to suppress the evaporation of the water in the drain pan.

When the fourth operation is completed, the first operation is completed.

<Second operation>
Depending on the model of the indoor unit (40), the control device (C) causes the second operation to be executed when the normal operation is completed when the automatic execution of the first mode is enabled. Strictly speaking, the control device (C) starts the second operation when the cooling operation, the dehumidifying operation and the heating operation are completed.

In the second operation, in principle, the control device (C) executes the fifth operation and the sixth operation in order.

Let ΔT5 be the execution time of the fifth operation, and ΔT6 be the execution time of the sixth operation. As a general rule, the execution time ΔT5 of the fifth operation is longer than the execution time ΔT6 of the sixth operation.

The details of the fifth operation and the sixth operation will be described with reference to FIG.

<Fifth operation>
The fifth operation is an operation of drying the water on the surface of the indoor heat exchanger (53) with the air carried by the indoor fan (52). By drying the water on the surface of the indoor heat exchanger (53), it is possible to suppress the growth of mold and bacteria on the surface of the indoor heat exchanger (53) as in the third operation in the first operation. The execution time ΔT5 of the fifth operation is 100 minutes in principle.

In the fifth operation, the control device (C) stops the compressor (21) and the outdoor fan (26). The control device (C) operates the indoor fan (52). In the fifth operation, the first refrigeration cycle and the second refrigeration cycle are not performed, and the refrigerant does not flow through the indoor heat exchanger (53). Therefore, the indoor heat exchanger (53) is stopped.

In the fifth operation, the air sucked from the suction port (46) of the indoor unit (40) passes through the indoor heat exchanger (53) in the stopped state. As a result, the water on the surface of the indoor heat exchanger (53) evaporates. The air used for drying the indoor heat exchanger (53) flows out to the target space from the outlet (47) of the indoor unit (40).

In the fifth operation, the control device (C) operates the drain pump (58). As a result, the water accumulated in the drain pan can be discharged to the outside of the casing (41) of the indoor unit (40).

<Sixth operation>
In the sixth operation, the control device (C) stops the compressor (21), the indoor fan (52) and the outdoor fan (26). In the sixth operation, the indoor unit (40) is substantially stopped.

In the sixth operation, the control device (C) operates the drain pump (58). Strictly speaking, the control device (C) continuously operates the drain pump (58) from the fifth operation to the sixth operation. As a result, the water remaining in the drain pan can be discharged to the outside of the casing (41) of the indoor unit (40). In addition, it is possible to suppress the backflow of water into the drain pan, and it is possible to suppress the evaporation of the water in the drain pan.

When the sixth operation is completed, the second operation is completed.

<Remote controller menu screen and instruction signal>
As shown in FIG. 6, the display unit (80) of the remote controller (C3) displays a menu screen (100) related to the operation of the air conditioner (10). The menu screen (100) includes a setting item (110) for normal operation of the air conditioner (10). The setting items (110) related to normal operation are the "ON timer" item (111) that sets the function to automatically start normal operation according to the time setting, and the "ON timer" item (111) that sets the function to automatically stop normal operation according to the time setting. It is an item (112) of "off timer".

As shown in FIGS. 7 and 8, the menu screen (100) displayed by the display unit (80) can include a setting item (120) relating to the first mode of the air conditioner (10). The setting item (120) relating to the first mode includes the third item (121) for setting the automatic start of the first mode. The setting item (120) relating to the first mode can further include a fourth item (122) for setting the type of the first mode.

In the remote controller (C3), the user uses the input unit (81) to set the setting item (110) related to normal operation and the setting item (120) related to the first mode displayed on the display unit (80). You can perform the setting operation. The remote controller (C3) is an example of an operation unit that accepts an operation for executing the first operation or the second operation. The setting item (120) relating to the first mode corresponds to the setting items relating to the first operation and the second operation.

When the third item (121) is selected in the display unit (80) of the remote controller (C3), the screen transitions to the first setting screen (130) shown in FIG. On the first setting screen (130), the fifth item (131) indicating the validity of the automatic start of the first mode and the sixth item (132) indicating the invalidity of the automatic start of the first mode are displayed so as to be selectable. To. On the first setting screen (130), the user can effectively set that the first mode is automatically started after the normal operation is completed by selecting the fifth item (131), and the sixth item (132). ) Can be disabled.

When it is enabled to automatically start the first mode on the first setting screen (130), the ON signal is sent from the transmitter (85) of the remote controller (C3) to the indoor unit (40M) which is the master unit. It is transmitted to the room control unit (C2) of. The ON signal is an instruction signal instructing to enable the automatic execution of the first mode. When the automatic start of the first mode is disabled on the first setting screen (130), the OFF signal is sent from the transmitter (85) of the remote controller (C3) to the indoor unit (40M) which is the master unit. It is transmitted to the indoor control unit (C2) of. The OFF signal is an instruction signal instructing to disable the automatic execution of the first mode.

When the fourth item (122) is selected in the display unit (80) of the remote controller (C3), the screen transitions to the second setting screen (140) shown in FIG. On the second setting screen (140), the first item (141) indicating the first operation and the second item (142) indicating the second operation are displayed so as to be selectable. The first item (141) is an item for executing the first operation. The second item (142) is an item for executing the second operation. The user can set the type of the first mode to the first operation by selecting the first item (141) on the second setting screen (140), and the second by selecting the second item (142). Can be set for driving.

When the type of the first mode is set to the first operation on the second setting screen (140), the first operation signal is transmitted from the transmitter (86) of the remote controller (C3) to the indoor unit (40M) which is the master unit. It is transmitted to the room control unit (C2) of. The first operation signal is an instruction signal instructing to execute the first operation as the first mode. When the type of the first mode is set to the second operation on the second setting screen (140), the second operation signal is transmitted from the transmitter (86) of the remote controller (C3) to the indoor unit (40M) which is the master unit. It is transmitted to the room control unit (C2) of. The second operation signal is an instruction signal instructing to execute the second operation as the first mode.

-Models of indoor unit and outdoor unit-
<Model of indoor unit>
The indoor unit (40) includes an indoor unit (40a) of model A, an indoor unit (40b) of model B, an indoor unit (40c) of model C, and an indoor unit (40d) of model D.

The indoor unit (40a) of model A is a model compatible with the first mode (first operation and second operation). The indoor unit (40a) of model A is an example of the second utilization unit. The indoor unit (40a) of model A is configured so that both the first operation and the second operation can be executed. Specifically, in the indoor unit (40a) of the model A, the software for executing the first operation and the software for executing the second operation are both stored in the memory (16) of the indoor control unit (C2). Will be done. In the indoor unit (40a) of the model A, the CPU (15) of the indoor control unit (C2) can identify the ON signal, the OFF signal, the first operation signal, and the second operation signal.

The indoor unit (40b) of model B is a compatible model of the first mode (first operation and second operation). The indoor unit (40b) of model B is an example of the second utilization unit. The indoor unit (40b) of model B is configured to be capable of performing the first operation. Specifically, in the indoor unit (40b) of the model B, the software for executing the first operation is stored in the memory (16) of the indoor control unit (C2). In the indoor unit (40b) of the model B, the CPU (15) of the indoor control unit (C2) can identify the ON signal, the OFF signal, and the first operation signal.

The indoor unit (40b) of model B is configured to be able to execute the second operation when the own unit (40b) is a slave unit and the indoor unit (40) which is the master unit executes the second operation. Will be done. Specifically, in the indoor unit (40b) of the model B, the software (16) of the indoor control unit (C2) stores the software for executing the second operation in the above case. In the indoor unit (40b) of the model B, the CPU (15) of the indoor control unit (C2) can identify the second operation signal. In the indoor unit (40b) of the model B, the CPU (15) of the indoor control unit (C2) may not be able to identify the second operation signal if the first operation signal and the other signals can be distinguished.

The indoor unit (40c) of model C is a compatible model of the first mode (second operation). The indoor unit (40c) of model C is an example of a first utilization unit and a third utilization unit. The indoor unit (40c) of model C is configured to be capable of performing the second operation. In the indoor unit (40c) of the model C, the software for executing the second operation is stored in the memory (16) of the indoor control unit (C2). In the indoor unit (40c) of the model C, the CPU (15) of the indoor control unit (C2) can identify the ON signal and the OFF signal.

The indoor unit (40c) of model C is configured so that the first operation cannot be executed. Specifically, in the indoor unit (40c) of the model C, the software for executing the first operation is not stored in the memory (16) of the indoor control unit (C2). In the indoor unit (40c) of the model C, the CPU (15) of the indoor control unit (C2) cannot discriminate between the first operation signal and the second operation signal.

The indoor unit (40d) of model D is a model that does not support the first mode (first operation and second operation). The indoor unit (40d) of the model D is an example of the first utilization unit and the fourth utilization unit. The indoor control unit (C2) of the indoor unit (40d) of the model D is configured so that both the first operation and the second operation cannot be executed. Specifically, in the indoor unit (40d) of the model D, the software for executing the first operation and the software for executing the second operation are both stored in the memory (16) of the indoor control unit (C2). Not done. In the indoor unit (40d) of the model D, the CPU (15) of the indoor control unit (C2) cannot discriminate any of the ON signal, the OFF signal, the first operation signal, and the second operation signal.

In both the indoor control unit (C2) of the indoor unit (40a) of model A and the indoor control unit (C2) of the indoor unit (40b) of model B, the own unit (40) is set as the master unit (40M). Then, when the power of the air conditioner (10) is turned on for the first time, after the second inquiry signal is transmitted from the transmission unit (17) to the indoor unit (40S) which is the slave unit, the indoor unit which is the slave unit ( The first inquiry signal is transmitted to the 40S) and the outdoor unit (20). The first inquiry signal is a signal inquiring whether or not the first operation can be executed. The second inquiry signal is a signal inquiring whether or not the second operation can be executed. When the own unit (40) is set to the master unit (40M), the indoor control unit (C2) of the indoor unit (40c) of model C is a slave unit when the power is turned on for the first time in the air conditioner (10). A second inquiry signal is transmitted from the transmission unit (17) to a certain indoor unit (40).

In the indoor unit (40a) of the model A and the indoor unit (40b) of the model B, the CPU (15) of the indoor control unit (C2) can identify the first inquiry signal and the second inquiry signal. In the indoor unit (40c) of the model C, the CPU (15) of the indoor control unit (C2) can identify the second inquiry signal. In the indoor unit (40c) of the model C, the CPU (15) of the indoor control unit (C2) cannot identify the first inquiry signal. In the indoor unit (40d) of the model D, the CPU (15) of the indoor control unit (C2) cannot discriminate between the first inquiry signal and the second inquiry signal.

When the indoor control unit (C2) of the indoor unit (40a) of model A receives the first inquiry signal by the receiving unit (18) when the own unit (40a) is set to the slave unit (40S), the CPU The first inquiry signal is identified by the operation of (15), and it is shown that the first operation can be executed from the transmission unit (17) to the indoor control unit (C2) of the indoor unit (40M) which is the master unit. Send a response signal.

When the indoor control unit (C2) of the indoor unit (40a) of model A receives the second inquiry signal by the receiving unit (18) when the own unit (40a) is set to the slave unit (40S), the CPU The second inquiry signal is identified by the operation of (15), and it is shown that the second operation can be executed from the transmission unit (17) to the indoor control unit (C2) of the indoor unit (40M) which is the master unit. Send a response signal.

In the indoor control unit (C2) of the indoor unit (40a) of model A, when the receiving unit (18) receives the ON signal, the operation of the CPU (15) identifies the ON signal, and the first operation is completed after the normal operation is completed. Automatic execution of the mode is enabled. In the indoor control unit (C2) of the indoor unit (40a) of model A, when the receiving unit (18) receives the ОFF signal, the operation of the CPU (15) identifies the OFF signal, and the first operation is completed after the normal operation is completed. Automatic mode execution is disabled.

In the indoor control unit (C2) of the indoor unit (40a) of model A, when the receiving unit (18) receives the first operation signal, the operation of the CPU (15) identifies the first operation signal, and the mode is set to the first mode. It is set to execute the first operation. With this setting, in the indoor unit (40a) of model A, the CPU (15) of the indoor control unit (C2) executes the first operation after the normal operation is completed when the automatic execution of the first mode is enabled. Control the indoor fan (52) and drain pump (58) to do so.

In the indoor control unit (C2) of the indoor unit (40a) of model A, when the receiving unit (18) receives the second operation signal, the operation of the CPU (15) identifies the second operation signal, and the mode is set to the first mode. It is set to execute the second operation. With this setting, in the indoor unit (40a) of model A, the CPU (15) of the indoor control unit (C2) executes the second operation after the normal operation is completed when the automatic execution of the first mode is enabled. Control the indoor fan (52) and drain pump (58) to do so.

When the indoor control unit (C2) of the indoor unit (40b) of model B receives the first inquiry signal by the receiving unit (18) when the own unit (40b) is set to the slave unit (40S), the CPU The first inquiry signal is identified by the operation of (15), and it is shown that the first operation can be executed from the transmission unit (17) to the indoor control unit (C2) of the indoor unit (40M) which is the master unit. Send a response signal.

When the indoor control unit (C2) of the indoor unit (40) of model B receives the second inquiry signal by the receiving unit (18) when the own unit (40b) is set to the slave unit (40S), the CPU The second inquiry signal is identified by the operation of (15), and a response indicating that the second operation can be executed from the transmitting unit (17) to the indoor control unit (C2) of the indoor unit (40M) of the master unit. Send signals other than signals. In this case, the indoor control unit (C2) of the indoor unit (40b) of the model B does not have to respond to the second inquiry signal.

In the indoor control unit (C2) of the indoor unit (40b) of model B, when the ON signal is received by the reception unit (18), the ON signal is identified by the operation of the CPU (15), and the first operation is completed after the normal operation is completed. Automatic execution of the mode is enabled. In the indoor control unit (C2) of the indoor unit (40b) of model B, when the OFF signal is received by the reception unit (18), the OFF signal is identified by the operation of the CPU (15), and the first operation is completed after the normal operation is completed. Automatic mode execution is disabled.

In the indoor unit (40b) of model B, the CPU (15) of the indoor control unit (C2) is enabled to automatically execute the first mode when its own unit (40b) is set to the master unit (40M). If present, the indoor fan (52) and drain pump (58) are controlled so that the first operation is executed after the normal operation is completed.

In the indoor control unit (C2) of the indoor unit (40b) of model B, the own unit (40b) is set to the slave unit (40S), and the indoor unit (40a) of model A is set to the master unit (40M). In this case, when the receiving unit (18) receives the first operation signal, the operation of the CPU (15) identifies the first operation signal, and it is set to execute the first operation as the first mode. Also in this case, in the indoor unit (40b) of the model B, if the automatic execution of the first mode is effective, the CPU (15) of the indoor control unit (C2) performs the first operation after the normal operation is finished. Control the indoor fan (52) and drain pump (58) to run.

In the indoor control unit (C2) of the indoor unit (40b) of model B, the own unit (40b) is set as the slave unit (40S), and the indoor unit (40a) of model A is set as the master unit (40M). In this case, when the receiving unit (18) receives the second operation signal, it is set to execute the second operation as the first mode. With this setting, in the indoor unit (40b) of model B, the CPU (15) of the indoor control unit (C2) executes the second operation after the normal operation is completed when the automatic execution of the first mode is enabled. Control the indoor fan (52) and drain pump (58) to do so.

In the indoor control unit (C2) of the indoor unit (40b) of model B, the own unit (40b) is set to the slave unit (40S), and the indoor unit (40c) of model C is set to the master unit (40M). When the ON signal is received, the ON signal is identified by the operation of the CPU (15), the automatic execution of the first mode is set to be valid, and the second operation is set to be executed as the first mode. To. Also in this case, in the indoor unit (40b) of model B, the CPU (15) of the indoor control unit (C2) has the indoor fan (52) and the drain pump so as to execute the second operation after the normal operation is completed. Control (58).

When the indoor control unit (C2) of the indoor unit (40c) of model C receives the first inquiry signal by the receiving unit (18) when the own unit (40c) is set to the slave unit (40S), the CPU It is determined that the first inquiry signal cannot be identified by the operation of (15), and the first operation can be executed from the transmission unit (17) to the indoor control unit (C2) of the indoor unit (40) which is the master unit. Send a signal other than the response signal shown. In this case, the indoor control unit (C2) of the indoor unit (40c) of the model C does not have to respond to the first inquiry signal.

When the indoor control unit (C2) of the indoor unit (40c) of model C receives the second inquiry signal by the receiving unit (18) when the own unit (40c) is set to the slave unit (40S), the CPU The second inquiry signal is identified by the operation of (15), and a response signal indicating that the second operation can be executed is transmitted from the transmission unit (17) to the indoor unit (40M) which is the master unit.

In the indoor control unit (C2) of the indoor unit (40c) of model C, when the ON signal is received by the reception unit (18), the ON signal is identified by the operation of the CPU (15), and the second operation is completed after the normal operation is completed. Performing a run is enabled. In the indoor control unit (C2) of the indoor unit (40c) of model C, when the receiving unit (18) receives the OFF signal, the CPU (15) operates to identify the OFF signal, and after the normal operation is completed, the second operation is completed. Performing a run is disabled. In the indoor unit (40c) of model C, when the automatic execution of the first mode is enabled, the CPU (15) of the indoor control unit (C2) executes the second operation after the normal operation is completed. Controls the fan (52) and drain pump (58).

When the indoor control unit (C2) of the indoor unit (40d) of model D receives the first inquiry signal by the receiving unit (18) when the own unit (40d) is set to the slave unit (40S), the CPU It is determined that the first inquiry signal cannot be identified by the operation of (15), and the first operation can be executed from the transmission unit (17) to the indoor control unit (C2) of the indoor unit (40M) which is the master unit. Send a signal other than the response signal shown. In this case, the internal control unit (C2) of the indoor unit (40d) of the model D does not have to respond to the first inquiry signal.

When the indoor control unit (C2) of the indoor unit (40d) of model D receives the second inquiry signal by the receiving unit (18) when the own unit (40d) is set to the slave unit (40S), the CPU The second inquiry signal cannot be identified by the operation of (15), and a signal other than the response signal indicating that the second operation can be executed from the transmitter (17) to the indoor unit (40M) which is the master unit is transmitted. Send. In this case, the internal control unit (C2) of the indoor unit (40d) of the model D does not have to respond to the second inquiry signal.

<Model of outdoor unit>
The outdoor unit (20) includes an outdoor unit (20q) of model Q and an outdoor unit (20r) of model R.

The outdoor unit (20q) of model Q is a compatible model of the first mode (first operation). The outdoor unit (20q) of model Q is an example of the second heat source unit. The outdoor unit (20q) of model Q is configured to be capable of performing the first operation. Specifically, in the outdoor unit (20q) of the model Q, the software for executing the first operation is stored in the memory (16) of the outdoor control unit (C1). In the outdoor unit (20q) of the model Q, the CPU (15) of the outdoor control unit (C1) can identify the first inquiry signal, the ON signal, the OFF signal, and the first operation signal.

When the outdoor control unit (C1) of the outdoor unit (20q) of the model Q receives the first inquiry signal by the receiving unit (18), the operation of the CPU (15) identifies the first inquiry signal and is the master unit. A response signal indicating that the first operation can be executed is transmitted from the transmission unit (17) to the indoor control unit (C2) of the indoor unit (40M).

In the outdoor control unit (C1) of the outdoor unit (20q) of model Q, when the receiving unit (18) receives the ON signal and the first operation signal, the operation of the CPU (15) identifies the ON signal and the first operation signal. However, it is effectively set to automatically execute the first mode after the normal operation is finished. In the outdoor unit (20q) of model Q, the CPU (15) of the outdoor control unit (C1) is a compressor so as to execute the first operation after the normal operation is completed when the automatic execution of the first mode is enabled. (21), outdoor heat exchanger (22), expansion valve (23), four-way switching valve (53) and outdoor fan (26) are controlled.

The outdoor unit (20r) of model R is a model that does not support the first mode (first operation). The outdoor unit (20r) of model R is an example of the first heat source unit. The outdoor unit (20r) of model R is configured so that the first operation cannot be executed. Specifically, in the outdoor unit (20r) of the model R, the software for executing the first operation is not stored in the memory (16) of the outdoor control unit (C1). In the outdoor unit (20r) of the model R, the CPU (15) of the outdoor control unit (C1) cannot discriminate the first inquiry signal, the ON signal, the OFF signal, the first operation signal, and the second operation signal.

When the outdoor control unit (C1) of the outdoor unit (20r) of the model R receives the first inquiry signal at the receiving unit (18), the operation of the CPU (15) cannot identify the first inquiry signal, and the master unit cannot identify the first inquiry signal. A signal other than the response signal indicating that the first operation can be executed is transmitted from the transmission unit (17) to a certain indoor unit (40). In this case, the outdoor control unit (C1) of the outdoor unit (20r) of the model R does not have to respond to the first inquiry signal.

-Determining the type of air conditioning unit by the indoor unit that is the master unit-
In both the indoor control unit (C2) of the indoor unit (40a) of model A and the indoor control unit (C2) of the indoor unit (40b) of model B, the own unit (40) is set as the master unit (40M). In this case, the receiving unit (18) receives the response signal for each of the first inquiry signal and the second inquiry signal from the indoor unit (40S), which is the slave unit, and the response signal for the first inquiry signal from the outdoor unit (20). ), The response signals are identified by the operation of the CPU (15), and the type of the air conditioning unit (15) is determined based on the response signals.

In the indoor control unit (C2) of the indoor unit (40a) of model A, the own unit (40a) is the master unit (40M), and the indoor unit (40S) and the outdoor unit (20) which are slave units for the first inquiry signal. ) Are all signals indicating that the first operation can be executed, the first determination signal is transmitted from the transmission unit (17) to the remote controller (C3). The first determination signal is a signal indicating that the air conditioning unit (15) is a type X air conditioning unit (15x) that allows selective execution of the first operation and the second operation.

In the indoor control unit (C2) of the indoor unit (40a) of model A, the own unit (40a) is the master unit (40M), and the response signal from the indoor unit (40S) which is the slave unit to the first inquiry signal is The signal other than indicating that the first operation can be executed is included, or the response signal from the outdoor unit (20) is a signal other than indicating that the first operation can be executed, and the second operation is possible. When all the response signals from the indoor unit (40S), which is the slave unit to the inquiry signal, are signals indicating that the second operation can be executed, the second determination signal is transmitted from the transmitter (17) to the remote controller (C3). ). The second determination signal is a signal indicating that the air conditioning unit (15) is a type Y air conditioning unit (15y) that is allowed to execute only one of the first operation and the second operation.

In the indoor control unit (C2) of the indoor unit (40a) of model A, the own unit (40a) is the master unit (40M), and the response signal from the indoor unit (40S) which is the slave unit to the second inquiry signal is When there is an indoor unit (40S) that is a slave unit that contains a signal other than indicating that the second operation can be executed or does not respond to the second inquiry signal, the third determination signal is transmitted. Send from (17) to the remote controller (C3). The third determination signal is a signal indicating that the air conditioning unit (15) is an air conditioning unit (15z) whose execution of both the first operation and the second operation is restricted.

In the indoor control unit (C2) of the indoor unit (40b) of model B, the own unit (40b) is the master unit (40M), and the indoor unit (40S) and the outdoor unit (20) which are slave units for the first inquiry signal. ) Is a signal indicating that the first operation can be executed, the second determination signal is transmitted from the transmission unit (17) to the remote controller (C3).

In the indoor control unit (C2) of the indoor unit (40b) of model B, the own unit (40b) is the master unit (40M), and the indoor unit (40S) and the outdoor unit (20) which are slave units for the first inquiry signal. The indoor unit (40S) or the outdoor unit (20), which is a slave unit that includes a signal other than indicating that the first operation can be executed or does not respond to the first inquiry signal. Is present, the third determination signal is transmitted from the transmission unit (17) to the remote controller (C3).

In the indoor control unit (C2) of the indoor unit (40c) of model C, the own unit (40c) is the master unit (40M), and the response signal from the indoor unit (40S) which is the slave unit to the second inquiry signal is When the signal indicates that the second operation can be executed, the second determination signal is transmitted from the transmission unit (17) to the remote controller (C3).

In the indoor control unit (C2) of the indoor unit (40c) of model C, the own unit (40c) is the master unit (40M), and the response signal from the indoor unit (40S) which is the slave unit to the second inquiry signal is When there is an indoor unit (40S) that is a slave unit that contains a signal other than indicating that the second operation can be executed or does not respond to the second inquiry signal, the third determination signal is transmitted. Send from (17) to the remote controller (C3).

The indoor control unit (C2) of the indoor unit (40d) of the model D transmits a signal different from the first determination signal and the second determination signal when the own unit (40d) is the master unit (40M). It is transmitted from the unit (17) to the remote controller (C3). In this case, the indoor control unit (C2) of the indoor unit (40M), which is the master unit, does not have to transmit the signal corresponding to the determination signal to the remote controller (C3).

-Limitations on the first mode-
The control device (C) limits the execution of the first operation when the outdoor unit (20) is the outdoor unit (20r) of the model R in which the first operation cannot be executed. The control device (C) limits the first operation when at least one indoor unit (40) is a model C indoor unit (40c) or a model D indoor unit (40d) in which the first operation cannot be executed. do. Strictly speaking, the control device (C) limits the execution of the first operation in all the indoor units (40) and the outdoor units (20) as a limitation of the first operation. The control device (C) further executes the first operation and the second operation when at least one indoor unit (40) is a model D indoor unit (40d) that cannot execute the first operation and the second operation. Limit the execution of.

The control device (C) controls the display of the remote controller (C3) to limit the execution of the first operation and the execution of the first operation and the execution of the second operation described above, and the user controls the remote controller. This is achieved by restricting the operations that can be performed in (C3).

<Remote controller display control>
As shown in FIG. 11, the CPU (83) of the remote controller (C3) is divided into a model of the indoor unit (40M) of the master unit and a model of the indoor unit (40S) of the slave unit constituting the air conditioning unit (15). The menu screen (100) displayed on the display unit (80) is changed accordingly. The contents shown in FIG. 11 are based on the premise that the outdoor unit (20) constituting the air conditioning unit (15) is the outdoor unit (20q) of the model Q.

In the table of FIG. 11, "S1" indicates that the first menu screen (100a) is displayed on the display unit (80) as the menu screen (100). As shown in FIG. 7, the first menu screen (100a) has the third item (121) for setting the automatic start of the first mode as the setting item (120) related to the first mode, and the first mode. It is a menu screen (100) including both the fourth item (122) for setting the type.

In the table of FIG. 11, "S2" indicates that the second menu screen (100b) is displayed on the display unit (80) as the menu screen (100). As shown in FIG. 8, the second menu screen (100b) includes the third item (121) as the setting item (120) related to the first mode, but does not include the fourth item (122). Is. On the second menu screen (100b), the fourth item (122) may be displayed in a non-selectable manner.

In the table of FIG. 11, “S3” indicates that the third menu screen (100c) is displayed on the display unit (80) as the menu screen (100). As shown in FIG. 6, the third menu screen (100c) is a menu screen (100) that does not include the setting item (120) related to the first mode. On the third menu screen (100c), both or one of the third item (121) and the fourth item (122) may be displayed as non-selectable as the setting item (120) related to the first mode.

When a plurality of indoor units (40S) of the slave unit are provided, the order of the menu screen (100) to be displayed preferentially to the display unit (80) is "S3", "S2", and "S1" in this order. be. In the table of FIG. 11, when the relationship between the indoor unit (40M) which is the master unit and the individual indoor unit (40S) which is the slave unit corresponds to "S1" and "S2", the second menu screen is displayed. (100b) is displayed, and if it corresponds to "S1" and "S3", "S2" and "S3", or "S1" and "S2" and "S3", the third menu screen (100c). Is displayed.

The menu screen (100) displayed on the display unit (80) is determined by the type of the air conditioning unit (15) according to the table of FIG. The remote controller (C3) limits the execution of the first operation and / or the execution of the second operation in the air conditioning unit (15) depending on the type of the air conditioning unit (15). In the memory (84) of the remote controller (C3), display control software that limits the execution of the first operation and the second operation is stored. The CPU (83) of the remote controller (C3) can identify the first determination signal, the second determination signal, and the third determination signal.

When the remote controller (C3) receives the first determination signal from the indoor unit (40M), which is the master unit, in the receiving unit (18), the remote controller (C3) identifies the first determination signal by the operation of the CPU (83). As shown in 7, the first menu screen (100a) including both the third item (121) and the fourth item (122) is displayed on the display unit (80). In this case, the user operates the input unit (81) of the remote controller (C3) to enable or disable the automatic execution of the first mode, and set the type of the first mode to the first operation. It can be set whether to use the second operation or the second operation.

When the remote controller (C3) receives the second determination signal from the indoor unit (40M), which is the master unit, in the receiving unit (18), the remote controller (C3) identifies the second determination signal by the operation of the CPU (83). As shown in 8, the second menu screen (100b) including the third item (121) but not the fourth item (122) is displayed on the display unit (80). In this case, the user can only set whether to enable or disable the execution of the first mode by operating the input unit (81) of the remote controller (C3).

When the remote controller (C3) receives the third determination signal from the indoor unit (40M), which is the master unit, in the receiving unit (18), the remote controller (C3) identifies the third determination signal by the operation of the CPU (83). As shown in 6, the third menu screen (100c), which does not include the setting item (120) related to the first mode, is displayed on the display unit (80). The CPU (83) of the remote controller (C3) receives a signal different from the first judgment signal and the second judgment signal, or does not receive a signal corresponding to the judgment signal from the indoor unit (40M) which is the master unit. Also in this case, the third menu screen (100c) is displayed on the display unit (80). In these cases, the user cannot make settings related to the first mode on the remote controller (C3).

-Operation of the indoor unit that is the master unit-
As shown in FIG. 12, the indoor unit (40M), which is a master unit, operates in response to an instruction signal from the remote controller (C3).

When the indoor unit (40a) of model A, which is the master unit, receives the first operation signal from the remote controller (C3), if the automatic execution of the first mode is enabled, the first operation is completed after the normal operation is completed. Perform a drive. When the indoor unit (40a) of model A, which is the master unit, receives the second operation signal from the remote controller (C3), if the automatic execution of the first mode is enabled, the second operation is completed after the normal operation is completed. Perform a drive. When the indoor unit (40a) of the model A, which is the master unit, receives the ON signal from the remote controller (C3) and does not receive the first operation signal, the indoor unit (40a) executes the second operation after the normal operation is completed.

When the indoor unit (40b) of the model B, which is the master unit, receives the ON signal from the remote controller (C3), it executes the first operation after finishing the normal operation.

When the indoor unit (40c) of the model C, which is the master unit, receives the ON signal from the remote controller (C3), it executes the second operation after finishing the normal operation.

-Operation of the indoor unit that is a slave unit-
As shown in FIG. 13, the indoor unit (40S), which is a slave unit, operates in response to an instruction signal from the indoor unit (40M), which is a master unit.

When the indoor unit (40a) of model A, which is a slave unit, receives the first operation signal from the indoor unit (40a) of model A, which is a master unit, it is usually considered that the automatic execution of the first mode is effective. The first operation is executed after the operation is completed. When the indoor unit (40a) of model A, which is a slave unit, receives a second operation signal from the indoor unit (40a) of model A, which is a master unit, it is usually considered that the automatic execution of the first mode is effective. The second operation is executed after the operation is completed. If the indoor unit (40a) of model A, which is a slave unit, receives an ON signal from the indoor unit (40a) of model A, which is a master unit, and does not receive the first operation signal, after the normal operation is completed. The second operation is executed.

When the indoor unit (40a) of the model A, which is the slave unit, receives the ON signal from the indoor unit (40b) of the model B, which is the master unit, the indoor unit (40a) executes the first operation after finishing the normal operation. When the indoor unit (40a) of the model A, which is the slave unit, receives the ON signal from the indoor unit (40c) of the model C, which is the master unit, the indoor unit (40a) executes the second operation after finishing the normal operation.

When the indoor unit (40b) of model B, which is a slave unit, receives the first operation signal from the indoor unit (40a) of model A, which is a master unit, it is usually said that the automatic execution of the first mode is effective. The first operation is executed after the operation is completed. When the indoor unit (40b) of the model B, which is the slave unit, receives the second operation signal from the indoor unit (40a) of the model A, which is the master unit, it is usually said that the automatic execution of the first mode is effective. The second operation is executed after the operation is completed. If the indoor unit (40b) of model B, which is a slave unit, receives an ON signal from the indoor unit (40a) of model A, which is a master unit, and does not receive the first operation signal, after the normal operation is completed. The second operation is executed.

When the indoor unit (40b) of the model B, which is the slave unit, receives the ON signal from the indoor unit (40b) of the model B, which is the master unit, the indoor unit (40b) executes the first operation after finishing the normal operation.

When the indoor unit (40b) of the model B, which is the slave unit, receives the ON signal from the indoor unit (40c) of the model C, which is the master unit, the indoor unit (40b) executes the second operation after finishing the normal operation.

When the indoor unit (40c) of model C, which is a slave unit, receives the second operation signal from the indoor unit (40a) of model A, which is a master unit, it is usually said that the automatic execution of the first mode is effective. The second operation is executed after the operation is completed. When the indoor unit (40c) of the model C which is the slave unit receives the ON signal from the indoor unit (40a) of the model A which is the master unit, the indoor unit (40c) executes the second operation after finishing the normal operation.

When the indoor unit (40c) of the model C which is the slave unit receives the ON signal from the indoor unit (40c) of the model C which is the master unit, the indoor unit (40c) executes the second operation after finishing the normal operation.

-Configuration example and operation of air conditioner-
<Type X air conditioning unit>
The type X air conditioning unit (15x) is an example of the first air conditioning unit. As shown in FIG. 14, in the air conditioning unit (15x) of the type X, the outdoor unit (20q) of the model Q is used as the outdoor unit (20). The indoor unit (40a) of model A is used as the indoor unit (40M) which is the master unit. The indoor unit (40S), which is a slave unit, is composed of at least one of the indoor unit (40a) of the model A and the indoor unit (40b) of the model B.

In the air conditioner (10) provided with the air conditioner unit (15x) of type X, the indoor control unit (C2) of the indoor unit (40M), which is the master unit, is the first to turn on the power of the air conditioner (10) for the first time. 1 The determination signal is transmitted from the transmission unit (17) to the remote controller (C3). The remote controller (C3) displays the first menu screen (100a) on the display unit (80) by the operation of the CPU (83) based on the first determination signal received by the reception unit (86). The first menu screen (100a) includes a third item (121) and a fourth item (122). As a result, the air conditioner (10) can selectively execute the first operation and the second operation.

In the air conditioner (10), when the type of the first mode is set to the first operation on the second setting screen (140), the automatic execution of the first mode is enabled on the first setting screen (130). When set, after the normal operation is completed, the plurality of indoor units (40) and the outdoor unit (20) execute the first operation. In the air conditioner (10), when the type of the first mode is set to the second operation on the second setting screen (140), the automatic execution of the first mode is enabled on the first setting screen (130). When set, the plurality of indoor units (40) execute the second operation after the normal operation is completed. In the air conditioner (10), when the automatic execution of the first mode is disabled on the first setting screen (140), the indoor unit (40) and the outdoor unit (20) are set after the normal operation is completed. Do not execute the first mode.

<Type Y air conditioning unit>
As shown in FIGS. 15 to 18, in the air conditioning unit (15y) of type Y, the indoor unit (40M) which is the master unit is the indoor unit of model B, or at least one indoor unit (40) is the model. The indoor unit (40c) of C or the outdoor unit (20) is the outdoor unit (20R) of model R.

However, the air conditioning unit (15) in which the indoor unit (40b) of model B is used for the indoor unit (40M) which is the master unit, and the indoor unit (40c) of model C is used for the indoor unit (40S) which is the slave unit. Does not correspond to the type Y air conditioning unit (15y). In the air conditioner (10) of this example, a plurality of indoor units (40) are controlled by a common instruction signal. From this, based on the ON signal, the indoor unit (40b) of model B executes the first operation, and the indoor unit (40c) of model C executes the second operation, and the same air conditioning unit (15) performs each other. This is to avoid a situation where different indoor units (40) execute different types of first modes.

The type Y air conditioning unit (15y) is divided into a type Y1 air conditioning unit (15y1) and a type Y2 air conditioning unit (15y2).

<Air conditioning unit of type Y1>
The air-conditioning unit (15y1) of the type Y1 is an air-conditioning unit (15) that is allowed to execute only the first operation. As shown in FIG. 15, in the air conditioning unit (15y1) of the type Y1, the indoor unit (40M) which is the master unit is the indoor unit (40b) of the model B. The indoor unit (40S), which is a slave unit, is composed of at least one of the indoor unit (40a) of the model A and the indoor unit (40b) of the model B. In the air conditioning unit (15y1) of the type Y1, the outdoor unit (20q) of the model Q is used as the outdoor unit (20).

In the air conditioner (10) provided with the air conditioner unit (15y1) of type Y1, the indoor unit (40M), which is the master unit, transmits a second determination signal when the power of the air conditioner (10) is turned on for the first time. Send from 17) to the remote controller (C3). The remote controller (C3) displays the second menu screen (100b) on the display unit (80) by the operation of the CPU (83) based on the second determination signal received by the reception unit (86). The second menu screen (100b) does not include the fourth item (122). Therefore, in the air conditioner (10), the execution of the second operation is restricted.

In the air conditioner (10) equipped with the air conditioning unit (15y1) of type Y1, when the automatic execution of the first mode is enabled on the first setting screen (130), after the normal operation is completed, a plurality of rooms are used. The unit (40) and the outdoor unit (20) perform the first operation. In the air conditioner (10), when the automatic execution of the first mode is disabled on the first setting screen (130), the indoor unit (40) and the outdoor unit (20) are set after the normal operation is completed. Do not execute the first mode.

<Air conditioning unit of type Y2>
The air-conditioning unit (15y2) of the type Y2 is an air-conditioning unit (15) that is allowed to execute only the second operation. In the air conditioning unit (15y2) of type Y2, as shown in FIGS. 16 and 17, at least one indoor unit (40) is a model C indoor unit (40c), or as shown in FIG. , The outdoor unit (20) is the model R outdoor unit (20r).

As shown in FIG. 16, in the air conditioning unit (15y2) of type Y2, when the indoor unit (40a) of model A is set as the master unit (40M), it is regarded as the indoor unit (40S) which is a slave unit. A model C indoor unit (40c) is included. When the air conditioning unit (15y2) of type Y2 includes an indoor unit (40) other than model C, the indoor unit (40) is at least one of the indoor unit (40a) of model A and the indoor unit (40b) of model B. Is.

As shown in FIG. 17, in the air conditioning unit (15y2) of type Y2, when the indoor unit (40a) of model C is set to the master unit (40M), the indoor unit (40S) which is a slave unit is It is composed of at least one of the indoor unit (40a) of model A and the indoor unit (40b) of model B. In this case, the indoor unit (40c) of the model C may be included as the indoor unit (40S) which is a slave unit.

As shown in FIG. 18, in the air conditioning unit (15y2) of type Y2, when the outdoor unit (20) is the outdoor unit (20r) of model R, each of the plurality of indoor units (40) is of model A. It is composed of at least one of the indoor unit (40a) and the model B indoor unit (40b). In this case, the indoor unit (40c) of the model C may be included as the indoor unit (40S) which is a slave unit.

In the air conditioner (10) provided with the air conditioner unit (15y2) of type Y2, the indoor unit (40M), which is the master unit, transmits a second determination signal when the power of the air conditioner (10) is turned on for the first time. Send from 17) to the remote controller (C3). The remote controller (C3) displays the second menu screen (100b) on the display unit (80) by the operation of the CPU (83) based on the second determination signal received by the reception unit (86). The second menu screen (100b) does not include the fourth item (122). Therefore, in the air conditioner (10), the execution of the first operation is restricted.

In the air conditioner (10) equipped with the air conditioning unit (15y2) of type Y2, when the automatic execution of the first mode is enabled on the first setting screen (130), after the normal operation is completed, a plurality of rooms are used. Each unit (40) performs a second operation. In the air conditioner (10), when the automatic execution of the first mode is disabled on the first setting screen (130), the indoor unit (40) and the outdoor unit (20) are set after the normal operation is completed. Do not execute the first mode.

<Type Z air conditioning unit>
As shown in FIGS. 19 and 20, in the type Z air conditioning unit (15z), the model Q outdoor unit (20q) may be used as the outdoor unit (20), and the model R outdoor unit (20r) may be used. ) May be used.

As shown in FIG. 19, in the type Z air conditioning unit (15z), in principle, at least one indoor unit (40) is the model D indoor unit (40d). When an indoor unit (40) other than model D is provided, the indoor unit (40) is either the model A indoor unit (40a), the model B indoor unit (40b), or the model C indoor unit (40c). There may be.

However, as an exception, as shown in FIG. 20, even if the air conditioning unit (15) does not have the indoor unit (40d) of the model D, the indoor unit (40M) which is the master unit is combined with the indoor unit (40b) of the model B. Is used, and when the indoor unit (40c) of model C is used for the indoor unit (40S) which is a slave unit, it corresponds to the air conditioning unit (15z) of type Z.

In the air conditioner (10) provided with the air conditioner unit (15z) of type Z, the indoor unit (40M), which is the master unit, transmits a third determination signal when the power of the air conditioner (10) is turned on for the first time. Send from 17) to the remote controller (C3). The remote controller (C3) displays the third menu screen (100c) on the display unit (80) by the operation of the CPU (83) based on the third determination signal received by the reception unit (86). The third menu screen (100c) does not include the third item (121) and the fourth item (122). Therefore, in the air conditioner (10), the execution of the first operation and the execution of the second operation are both restricted.

According to the first embodiment, when the outdoor unit (20) is the outdoor unit (20r) of the model R, or the plurality of indoor units (40) are the indoor unit (40c) of the model C or the indoor unit of the model D ( When 40d) is included, the first operation is restricted. Therefore, when the air conditioner (10) includes the outdoor unit (20r) of model Q, the indoor unit (40c) of model C, or the indoor unit (40d) of model D, it cannot operate properly in the first operation. Can be avoided. Thereby, the first operation in which the plurality of indoor units (40) and the outdoor unit (20) operate together can be appropriately executed.

According to the first embodiment, as a limitation of the first operation, the execution of the first operation in all the indoor units (40) and the outdoor units (20) is restricted. Therefore, the relatively simple configuration and control of the air conditioner (10) avoids the situation where the air conditioner (10) cannot operate properly in the first operation.

According to the first embodiment, when the indoor unit (40a) of the model A and the indoor unit (40c) of the model C are provided as the indoor unit (40), the second operation is started when the cooling operation is completed. In the cooling operation, dew condensation water may occur in each indoor heat exchanger (53). In the second operation, each indoor heat exchanger (53) is dried by the air carried by the indoor fan (52). Therefore, even if the air conditioner (10) is provided with the indoor unit (40c) of the model C and the execution of the first operation is restricted and the second operation cannot be performed, each indoor heat exchanger (the second operation is performed). 53) can be dried.

According to the first embodiment, as the indoor unit (40), at least one of the indoor unit (40a) of the model A, the indoor unit (40b) of the model B, and the indoor unit (40c) of the model C, and the indoor unit of the model D. When equipped with the unit (40d), the execution of the second operation in all the indoor units (40) is restricted. In this case, the execution of the second operation in the plurality of indoor units (40) can be controlled in common.

According to the first embodiment, both the outdoor unit (20) and the plurality of indoor units (40) can execute the first operation, and each of the plurality of indoor units (40) can execute the second operation. In the case of, the display unit (80) displays the first item (141) for executing the first operation and the second item (142) for executing the second operation in a selectable manner. .. In this case, by operating the remote controller (C3) to select either the first item (141) or the second item (142), the first operation or the second operation is executed according to the selected item. Can be made to.

According to the first embodiment, as the indoor unit (40), the utilization unit (40c) of the model C, which cannot execute the first operation but can execute the second operation, and the first operation and the second operation are executed. When the unit (40a) for using the possible model A is provided, the first item (141) for executing the first operation is not displayed on the display unit (80). As a result, the remote controller (C2) cannot select the first item (141), and the execution of the first operation can be restricted. Further, it is possible to prevent the user from mistakenly selecting the first item (141).

According to the first embodiment, in a plurality of indoor units (40), at least one of the indoor unit (40a) of model A, the indoor unit (40b) of model B, and the indoor unit (40c) of model C, and the model. When the indoor unit (40d) of D is mixed, the setting item (120) relating to the first operation and the second operation is not displayed or is displayed as non-selectable on the display unit (80). As a result, the remote controller (C3) cannot operate the setting item (120), and the execution of the first operation and the second operation can be restricted. In addition, it is possible to prevent the user from misunderstanding that the setting for the first mode can be performed.

<< Embodiment 2 >>
In the second embodiment, the technique of the present disclosure will be described by exemplifying a multi-type air conditioner having a plurality of refrigerant systems as an example.

<Overall configuration of air conditioner>
As shown in FIG. 21, the air conditioner (10) of the second embodiment includes a plurality of air conditioning units (15) and a remote controller (C3). The communication unit (82) of the remote controller (C3) is wired or wired via the communication unit (14) of the indoor unit (40M), which is the master unit of each of the plurality of air conditioning units (15), and the third communication line (L3). Connected wirelessly. The configuration of each air conditioning unit (40), the configuration of the remote controller (C3), and the transmission / reception of signals between the outdoor unit (20), the indoor unit (40), and the remote controller (C3) are described in the above-described first embodiment. Since it is the same as the above, the detailed description of the same matters as in the first embodiment will be omitted.

The indoor control unit (C2) of the indoor unit (40M), which is the master unit of each air conditioning unit (15), is the indoor unit (40a) of model A, the indoor unit (40b) of model B, or the indoor unit (40c) of model C. ), The type of the air conditioning unit (15) to which the own unit (40M) belongs is determined when the power of the air conditioning device (10) is turned on for the first time, as in the first embodiment, and the air conditioning unit (10) is determined. The determination signal (first determination signal, second determination signal, or third determination signal) according to the type of 15) is transmitted from the transmission unit (85) to the remote controller (C3).

When the indoor control unit (C2) of the indoor unit (40M), which is the master unit of each air conditioning unit (15), is the indoor unit (40d) of model D, when the power is turned on for the first time in the air conditioner (10). , A signal different from the first determination signal and the second determination signal is transmitted from the transmission unit (85) to the remote controller (C3). In this case, the indoor control unit (C2) of the indoor unit (40M), which is the master unit of each air conditioning unit (15), does not have to transmit the signal corresponding to the determination signal to the remote controller (C3).

-Limitations on the first mode-
The control device (C) limits the execution of the first operation in each of the plurality of air conditioning units (15) when the outdoor unit (20) is the outdoor unit (20r) of the model R in which the first operation cannot be executed. do. The control device (C) is a model C indoor unit (40c) or a model D indoor unit (40d) in which at least one indoor unit (40) cannot execute the first operation in each of the plurality of air conditioning units (15). If this is the case, the execution of the first operation is restricted. The control device (C) is a model D indoor unit (40d) in which at least one indoor unit (40) cannot execute the first operation and the second operation in each of the plurality of air conditioning units (15). The execution of the first operation and the execution of the second operation are restricted.

The control device (C) controls the display of the remote controller (C3) to limit the execution of the first operation and the execution of the first operation and the second operation described above for each air conditioning unit (15). Therefore, the operation that the user can perform with the remote controller (C3) is restricted, and the indoor unit that is the slave unit is controlled by the indoor control unit (C2) of the indoor unit (40M) that is the master unit of each air conditioning unit (15). This is achieved by having the (40) and the outdoor unit (20) perform unified operations.

<Remote controller display control>
As shown in FIG. 22, the CPU (83) of the remote controller (C3) displays a menu on the display unit (80) according to the combination of a plurality of air conditioning units (15) constituting the air conditioner (10). Change the screen (100).

In the table of FIG. 22, the meanings of "S1", "S2" and "S3" are the same as the table of FIG. 11 referred to in the first embodiment. When three or more air conditioning units (15) are provided, the order of the menu screen (100) to be displayed preferentially to the display unit (80) is "S1", "S2", and "S3". .. In the table of FIG. 22, the relationship between a pair of air conditioning units (15) different from each other is as follows: "S1" and "S2", "S1" and "S3", or "S1" and "S2" and "S3". If applicable, the first menu screen (100a) is displayed. When the relationship between the pair of air conditioning units (15) different from each other corresponds to "S2" and "S3" in the table of FIG. 22, the second menu screen (100b) is displayed.

The menu screen (100) displayed on the display unit (80) is determined by the type of the individual air conditioning unit (15) according to the table of FIG. Thereby, the remote controller (C3) limits the execution of both or one of the first operation and the second operation in each air conditioning unit (15) in each of the plurality of air conditioning units (15).

When the remote controller (C3) receives the first determination signal from the indoor unit (40M), which is the master unit of any of the air conditioning units (15), in the receiving unit (18) among the plurality of air conditioning units (15). Displays the first menu screen (100a) including both the third item (121) and the fourth item (122), as shown in FIG. 7. In this case, the user operates the remote controller (C3) to enable or disable the automatic execution of the first mode, and set the type of the first mode to the first operation or the second operation. You can set whether to do it or not.

In the remote controller (C3), the determination signal received from the indoor unit (40M) which is the master unit of each of the plurality of air conditioning units (15) is not the first determination signal, and the determination signal of any of the air conditioning units (15). When the determination signal received from the indoor unit (40M), which is the master unit, is the second determination signal, the third item (121) is included but the fourth item (122) is not included, as shown in FIG. Display the second menu screen (100b). In this case, the user can only set whether to enable or disable the execution of the first mode by operating the input unit (81) of the remote controller (C3).

When the determination signal received from the indoor unit (40M) which is the master unit of each of the plurality of air conditioning units (15) is the third determination signal, the remote controller (C3) is as shown in FIG. Display the third menu screen (100c) that does not include the setting item (120) related to the first mode. In this case, the user cannot make settings related to the first mode on the remote controller (C3).

<Control of the indoor unit that is the master unit of each air conditioning unit>
As shown in FIG. 23, the indoor control unit (C2) of the indoor unit (40), which is the master unit of each air conditioning unit (15), has each air conditioning unit for the first mode based on the instruction signal of the remote controller (C3). Have (15) operate according to the type.

In the air conditioning unit (15x) of type X, when the indoor control unit (C2) of the indoor unit (40M), which is the master unit, receives the first operation signal from the remote controller (C3) by the receiving unit (18). When the automatic execution of the first mode is enabled, the first operation is executed by the operation of the CPU (15) after the normal operation is finished. Then, the indoor control unit (C2) of the indoor unit (40M), which is the master unit, causes the indoor unit (40S) and the outdoor unit (20), which are slave units, to execute the first operation. This operation is the same regardless of whether the indoor unit (40M) which is the master unit is the indoor unit (40a) of the model A or the indoor unit (40b) of the model B.

In the air conditioning unit (15x) of type X, when the indoor control unit (C2) of the indoor unit (40), which is the master unit, receives the second operation signal from the remote controller (C3) by the receiving unit (18). When the automatic execution of the first mode is enabled, the second operation is executed by the operation of the CPU (15) after the normal operation is finished. Then, the indoor control unit (C2) of the indoor unit (40M), which is the master unit, causes the indoor unit (40S), which is the slave unit, to execute the second operation. This operation is the same regardless of whether the indoor unit (40) which is the master unit is the indoor unit (40a) of the model A or the indoor unit (40b) of the model B.

In the air conditioning unit (15y) of type Y1, when the indoor control unit (C2) of the indoor unit (40M), which is the master unit, receives the ON signal from the remote controller (C3) by the receiving unit (18), it operates normally. After the end, the first operation is executed by the operation of the CPU (15). Then, the indoor control unit (C2) of the indoor unit (40M), which is the master unit, causes the indoor unit (40S) and the outdoor unit (20), which are slave units, to execute the first operation. This operation is the same regardless of whether the indoor unit (40M), which is the master unit, is the indoor unit (40a) of model A or the indoor unit (40b) of model B, and is the first operation signal. Or it is the same whether or not the second operation signal is received.

In the air conditioning unit (15y) of type Y2, when the indoor control unit (C2) of the indoor unit (40M), which is the master unit, receives the ON signal from the remote controller (C3) by the receiving unit (18), the first operation is performed. After the normal operation is finished, the second operation is executed by the operation of the CPU (15) regardless of whether or not the signal or the second operation signal is received. Then, the indoor control unit (C2) of the indoor unit (40M), which is the master unit, causes the indoor unit (40S), which is the slave unit, to execute the second operation. In this operation, the indoor unit (40M) which is the master unit is the indoor unit (40a) of the model A, the indoor unit (b) of the model B, or the indoor unit (40c) of the model C. It is the same regardless of whether or not the first operation signal or the second operation signal is received or not.

-Configuration example and operation of air conditioner-
As shown in FIG. 24, in the air conditioner (10), when at least one air conditioning unit (15) among the plurality of air conditioning units (15) is a type X air conditioning unit (15x), the type X In the air conditioning unit (15), the indoor unit (40M), which is the master unit, transmits the first determination signal from the transmission unit (17) to the remote controller (C3) when the power is turned on for the first time. The remote controller (C3) displays the first menu screen (100a) on the display unit (80) by the operation of the CPU (83) based on the first determination signal received by the reception unit (86).

In the air conditioner (10), when the type of the first mode is set to the first operation on the second setting screen (140), the automatic execution of the first mode is enabled on the first setting screen (130). When set, after the normal operation is completed, each indoor unit (40) and the outdoor unit (20) execute the first operation in the air conditioning unit (15x) of the type X. In the air conditioner (10), when the type of the first mode is set to the second operation on the second setting screen (140), the automatic execution of the first mode is enabled on the first setting screen (130). When set, after the normal operation is completed, each indoor unit (40) and the outdoor unit (20) execute the second operation in the air conditioning unit (15x) of the type X.

When the air conditioner (10) is provided with an air conditioner unit (15y1) of type Y1, if the automatic execution of the first mode is enabled on the first setting screen (130), after the normal operation is completed. , In the air conditioning unit (15y1) of type Y1, each indoor unit (40) and the outdoor unit (20) execute the first operation. When the air conditioner (10) is provided with an air conditioner unit (15y) of type Y2, if the automatic execution of the first mode is enabled on the first setting screen (130), after the normal operation is completed. , Each indoor unit (40) executes the second operation in the air conditioning unit (15y2) of type Y2. When the air conditioner (10) is provided with an air conditioner unit (15z) of type Z, if the automatic execution of the first mode is enabled on the first setting screen (130), after the normal operation is completed. , In the type Z air conditioning unit (15z), the indoor unit (40) and the outdoor unit (20) do not execute the first mode.

As shown in FIG. 25, in the air conditioner (10), at least one air conditioning unit (15) among the plurality of air conditioning units (15) is a type Y1 air conditioning unit (15y1) and a type Y2 air conditioning unit (15y2). ), The indoor unit (40M), which is the master unit of the air-conditioning unit (15y1) of type Y1 or the air-conditioning unit (15y2) of type Y2, transmits the second determination signal when the power is turned on for the first time. Send from (17) to the remote controller (C3). The remote controller (C3) displays the second menu screen (100b) on the display unit (80) by the operation of the CPU (83) based on the second determination signal received by the reception unit (86). Therefore, in the air conditioner (10), the execution of the first operation is restricted in the air conditioning unit (15y2) of the type Y2 in which the first operation should not be performed, and the air conditioning of the type Y1 in which the second operation should not be performed. In the unit (15y2), the execution of the second operation is restricted.

In the air conditioner (10), when the automatic execution of the first mode is enabled on the first setting screen (130), the air conditioning unit (15y1) of the type Y1 is provided after the normal operation is completed. In the air conditioning unit (15y1) of the type Y1, each indoor unit (40) and the outdoor unit (20) execute the first operation. When the air conditioner (10) is provided with an air conditioner unit (15y) of type Y2, if the automatic execution of the first mode is enabled on the first setting screen (130), after the normal operation is completed. , Each indoor unit (40) executes the second operation in the air conditioning unit (15y2) of type Y2. When the air conditioner (10) is provided with an air conditioner unit (15z) of type Z, if the automatic execution of the first mode is enabled on the first setting screen (130), after the normal operation is completed. , In the type Z air conditioning unit (15z), the indoor unit (40) and the outdoor unit (20) do not execute the first mode.

As shown in FIG. 26, in the air conditioner (10), when each of the plurality of air conditioning units (15) is a type Z air conditioning unit (15z), the room which is the master unit in each air conditioning unit (15). The unit (40M) transmits the third determination signal from the transmission unit (17) to the remote controller (C3) when the power is turned on for the first time, or does not transmit the determination signal. The remote controller (C3) displays the third menu on the display unit (80) by the operation of the CPU (83) based on the third determination signal received by the receiving unit (86) or not receiving the determination signal. Display the screen (100c). The third menu screen (100c) does not include the setting item (120) related to the first mode. Therefore, in the air conditioner (10), the execution of the first operation and the execution of the second operation are both restricted.

According to the second embodiment, the outdoor unit (20r) of the model Q in which the first operation cannot be executed, or the indoor unit (40c) of the model C or the indoor unit (40d) of the model D in which the first operation cannot be executed. In this case, the execution of the first operation of the air conditioning unit (15) including the outdoor unit (20r) or the indoor unit (40c, 40d), which is a model not compatible with the first operation, is restricted. As a result, in the air conditioner (10) provided with the plurality of air conditioning units (15), the first operation can be appropriately executed by avoiding the situation where the first operation cannot be properly operated for each air conditioning unit (15).

According to the second embodiment, when at least one air-conditioning unit (15) is a type X air-conditioning unit (15x) that is allowed to execute the first operation, the display unit (80) performs the first operation. The first item (141) for executing the second operation and the second item (142) for executing the second operation are displayed in a selectable manner. In this case, by operating the remote controller (C3) to select either the first item (141) or the second item (142), the air conditioning unit (15x) of type X can be selected according to the selected item. The first operation or the second operation can be executed.

<< Other Embodiments >>
In the above-described embodiment, the following configuration may be used as long as it is applicable.

<Target space>
The target space of the air conditioner is not limited to the indoor space. The target space may be an interior space such as a warehouse, or may be a space inside a factory.

<Indoor unit, outdoor unit>
The indoor unit (40) may be arranged on the front side of the ceiling surface and may be suspended from the top surface. The indoor unit (40) may be arranged on the back side of the top surface and suspended from a beam on the ceiling. The indoor unit (40) may have one or both of the suction duct and the outlet duct. The suction duct constitutes a flow path for sucking indoor air into the air passage. The outlet duct constitutes a flow path for supplying air that has passed through the utilization heat exchanger (53) into the room. The indoor unit (40) may be a wall-mounted type or a floor-standing type.

The indoor unit (40a) of the model A and the indoor unit (40b) of the model B may have a notification unit for notifying that the first operation can be executed. The notification unit may be a lamp composed of LEDs or the like, a liquid crystal monitor, or a sticker. The notification unit may be one that sounds a sound to notify. According to this, the notification unit can notify the user that the indoor unit (40a) of the model A and the indoor unit (40b) of the model B are compatible models for the first operation.

The outdoor unit (40q) of the model Q may have a notification unit for notifying that the first operation can be executed. The notification unit may be a lamp composed of LEDs or the like, a liquid crystal monitor, or a sticker. The notification unit may be one that sounds a sound to notify. According to this, the outdoor unit (20q) of the model Q can notify the user that the model is compatible with the first operation by the notification unit.

<Air conditioner>
In the air conditioner (10), the plurality of indoor units (40) do not have to be divided into a master unit (40M) and a slave unit (40S). In the air conditioner (10), each indoor control unit (C2) of the plurality of indoor units (40) may be connected to the remote controller (C3) by wire or wirelessly. The remote controller (C2) may directly transmit an instruction signal to each indoor control unit (C2). The outdoor control unit (C1) of the outdoor unit (20) may be connected to the remote controller (C3) by wire or wirelessly. The remote controller (C2) may send an instruction signal directly to the outdoor control unit (C1).

The air conditioner (10) may be a pair type having one outdoor unit (20) and one indoor unit (40). In the paired air conditioner (10), the control device (C) may limit the execution of the first operation when the outdoor unit (20) or the indoor unit (40) cannot execute the first operation. .. As an example of such an embodiment, in the remote controller (C3), the outdoor unit (20) is the outdoor unit (20r) of the model R, or the indoor unit (40) is the indoor unit (40c, 40d) of the model C or the model D. ), By displaying the second menu screen (100b) or the third menu screen (100c) on the display unit (80), the execution of the first operation on the air conditioner (10) is restricted. You may.

The air conditioner (10) may include a plurality of outdoor units (20). In an air conditioner (10) having a plurality of outdoor units (20), the control device (C) limits the execution of the first operation when at least one outdoor unit (20) cannot execute the first operation. do it. As an example of such an embodiment, the remote controller (C3) displays the second menu screen (100b) or the second menu screen (100b) on the display unit (80) when at least one outdoor unit (20) is the outdoor unit (20r) of the model R. 3 By displaying the menu screen (100c), the execution of the first operation in the air conditioner (10) may be restricted.

The air conditioner (10) may be of a method in which heating is performed in some indoor units (40) and cooling is performed in another indoor unit (40) at the same time.

The air conditioner (10) may be of a type in which a flow path switching valve is provided in the refrigerant circuit (11) and a part of the flow paths can be separated from the refrigerant circuit (11) to perform a refrigeration cycle. In the air conditioner (10) in which the flow path switching valve is provided in the refrigerant circuit (11), the control device (C) is an outdoor unit (20r) or an indoor unit (40c, 40d) that is not compatible with the first operation. ) Is separated from the refrigerant circuit (11) to limit the execution of the first operation in the outdoor unit (20r) or indoor unit (40c, 40d), which is the non-compatible model. The first operation may be executed by the outdoor unit (20q) and the indoor unit (20a, 20b) which are compatible models of the first operation.

In the air conditioner (10), the controller (C) may not be able to perform the first operation if at least one outdoor unit (20) is unable to perform the first operation, or if at least one indoor unit (40) is unable to perform the first operation. If the air conditioning unit (15) as a whole cannot execute the first operation, or the outdoor unit (20) in which the first operation cannot be executed or the indoor unit (40) in which the first operation cannot be executed. The first operation may be restricted by preventing the first operation from being executed.

<Control device>
The control device (C) may be provided only in the indoor unit (40) or may be provided only in the outdoor unit (20). The control device (C) may be a centralized management device separate from the indoor unit (40) and the outdoor unit (20).

The remote controller (C3) transmits the first inquiry signal and the second inquiry signal to each indoor unit (40) and outdoor unit (20) in place of the indoor control unit (C2) of the indoor unit (40M) which is the master unit. You may. Even if the remote controller (C3) aggregates the response signals from the indoor unit (40) and the outdoor unit (20) to the first inquiry signal and the second inquiry signal, and determines the type of the air conditioning unit (15). good.

The outdoor control unit (C1) may transmit the first inquiry signal and the second inquiry signal to each indoor unit (40) in place of the indoor control unit (C2) of the indoor unit (40M) which is the master unit. The outdoor control unit (C1) may aggregate the response signals from each indoor unit (40) to the first inquiry signal and the second inquiry signal. The outdoor control unit (C1) may determine the type of the air conditioning unit (15) and transmit a determination signal indicating the determination result to the remote controller (C3).

The remote controller (C3) can identify whether or not the outdoor unit (20) is the model R outdoor unit (20r) by receiving a response signal from the outdoor unit (20) to the first inquiry signal. Information may be displayed on the display unit (80). According to this, when the air conditioner (10) is equipped with the outdoor unit (20r) of the model R, the existence of the outdoor unit (20r), which is a model not compatible with the first operation, is confirmed by the display unit (80). can.

The remote controller (C3) receives response signals from each of the plurality of indoor units (40) for the first inquiry signal and the second inquiry signal, and each indoor unit (40) is a model C indoor unit (40c). ) Or information that can identify whether or not it is the indoor unit (40d) of the model D may be displayed on the display unit (80). According to this, when the air conditioner (10) includes the indoor unit (40c) of model C or the indoor unit (40d) of model D, the indoor unit (40c, 40d) which is a non-compatible model of the first operation. Can be confirmed on the display unit (80).

<First mode>
The first operation may be an operation of producing ice in the indoor heat exchanger (53) as an evaporator. In the first operation, ice is formed on the surface of the indoor heat exchanger (53). Subsequent second operation removes this ice from the surface of the indoor heat exchanger (53). As a result, the indoor heat exchanger (53) can be cleaned.

The first operation may be an operation in which dew condensation water is generated on the surface of the indoor heat exchanger (53), and includes a cooling operation and a dehumidifying operation. Specifically, the control device (C) may perform a cooling operation or a dehumidifying operation as the first operation, and then execute the third operation and the second operation in order. Also in this control, the execution time of the second operation may be shorter than the execution time of the third operation.

The first operation may be an operation including a first operation, a third operation, and a fourth operation. The first operation may be an operation including the first operation and the third operation. The first operation may be an operation performed for a purpose other than cleaning the indoor heat exchanger (53). The first operation may include the first operation and may be an operation in which the outdoor unit (20) and the indoor unit (40) operate together.

The second operation may be an operation including the fifth operation. The second operation may include a seventh operation of heating the surface of the indoor heat exchanger (53) by flowing a refrigerant through the heat transfer tube of the indoor heat exchanger and drying the surface. The seventh operation may be the same operation as the second operation of the first operation.

Although the embodiments and modifications have been described above, it will be understood that various modifications of the forms and details are possible without departing from the spirit and scope of the claims. Further, the above embodiments, modifications, and other embodiments may be appropriately combined or replaced as long as the functions of the subject of the present disclosure are not impaired.

The descriptions "1st", "2nd", "3rd" ... described above are used to distinguish the words and phrases to which these descriptions are given, and the number and order of the words and phrases are also limited. It's not something to do.

The present disclosure is useful for air conditioners.

10 Air conditioner 11 Refrigerant circuit 15 Air conditioning unit 15 x Type X air conditioning unit (first air conditioning unit)
20 Outdoor unit (heat source unit)
20q Model Q outdoor unit (second heat source unit)
20r model R outdoor unit (first heat source unit)
21 Compressor 22 Outdoor heat exchanger (heat source heat exchanger)
23 Expansion valve (pressure reducing mechanism)
40 Indoor unit (utilization unit)
40a Model A indoor unit (second use unit)
40b Model B indoor unit (second use unit)
40c Model C indoor unit (1st utilization unit, 3rd utilization unit)
40d Model D indoor unit (1st utilization unit, 4th utilization unit)
52 Indoor fan (blower)
53 Indoor heat exchanger (utilized heat exchanger)

Claims (11)

A refrigerant circuit (11) that includes a compressor (21), at least one heat source heat exchanger (22), a decompression mechanism (23) and at least one utilization heat exchanger (53) to perform a refrigeration cycle.
At least one heat source unit (20) provided with the heat source heat exchanger (22) and
At least one utilization unit (40) provided with the utilization heat exchanger (53) and
A control device (C) for controlling the heat source unit (20) and the utilization unit (40) so as to execute the first operation is provided.
The first operation is an operation including a first operation of performing a first refrigeration cycle using the utilization heat exchanger as an evaporator to generate dew condensation water or ice in the utilization heat exchanger (53).
The control device (C) includes a first heat source unit (20r) in which the heat source unit (20) cannot execute the first operation, or the utilization unit (40) cannot execute the first operation. An air conditioner comprising a first utilization unit (40c, 40d), which limits instructions for executing the first operation. A refrigerant circuit (11) that includes a compressor (21), at least one heat source heat exchanger (22), a decompression mechanism (23) and at least one utilization heat exchanger (53) to perform a refrigeration cycle.
At least one heat source unit (20) provided with the heat source heat exchanger (22) and
A plurality of utilization units (40) provided with the utilization heat exchanger (53), and
A control device (C) for controlling the heat source unit (20) and the utilization unit (40) so as to execute the first operation is provided.
The first operation is an operation including a first operation of performing a first refrigeration cycle using the utilization heat exchanger as an evaporator to generate dew condensation water or ice in the utilization heat exchanger (53).
The control device (C) includes a first heat source unit (20r) in which the heat source unit (20) can not execute the first operation , or the utilization unit (40) can not execute the first operation. An air conditioner comprising, when including a first utilization unit (40c, 40d), limiting the execution of the first operation in all the utilization units (40) and the heat source unit (20). In the air conditioner according to claim 1 or 2.
The first operation includes a second operation performed after the first operation.
The second operation is an operation in which the second refrigeration cycle using the utilization heat exchanger (53) as a radiator is performed in the refrigerant circuit (11), and the air is heated by the utilization heat exchanger (53). An air conditioner featuring. In the air conditioner according to claim 3,
The utilization unit (40) has a blower (52) that conveys air passing through the utilization heat exchanger (53).
As the utilization unit (40), the second utilization unit (40a) capable of executing the second operation of operating the blower (52) with the first operation and the heat exchange of the utilization heat exchanger (53) stopped. , 40b) and the third utilization unit (40c), which is the first utilization unit capable of executing the second operation, the first refrigeration cycle is performed, and the utilization heat exchanger (53) is used. When the cooling operation for cooling the air and air-conditioning the target space is completed, the second operation is started for each of the second utilization unit (40a, 40b) and the third utilization unit (40c). Harmonizer. In the air conditioner according to claim 4,
The control device (C) includes at least one of the second utilization unit (40a, 40b) and the third utilization unit (40c) as the utilization unit (40), and the second operation incapable of executing the second operation. An air conditioner comprising, when a fourth utilization unit (40d) which is one utilization unit (40c, 40d) is provided, the execution of the second operation in all the utilization units (40) is restricted. In the air conditioner according to any one of claims 1 to 5, the air conditioner
Further, an operation unit (C3) for receiving an operation for executing the first operation or the second operation is provided.
The operation unit (C3) has a display unit (80) for displaying setting items (120) related to the first operation and the second operation.
The utilization unit (40) has a blower (52) that conveys air passing through the utilization heat exchanger.
The heat source unit (20) is a second heat source unit (20q) capable of performing the first operation, and the utilization unit (40) is the heat of the first operation and the utilization heat exchanger (53). In the case of the second utilization unit (40a, 40b) capable of executing the second operation of operating the blower (52) with the replacement stopped, the display unit (80) is set as the setting item (120). An air conditioner characterized in that a first item (141) for executing the first operation and a second item (142) for executing the second operation are selectively displayed. In the air conditioner according to any one of claims 4 to 6, the air conditioner
Further, an operation unit (C3) for receiving an operation for executing the first operation or the second operation is provided.
The operation unit (C3) has a display unit (80) for displaying setting items (120) related to the first operation and the second operation.
The utilization unit (40) includes a third utilization unit (40c) which is the first utilization unit (40c, 40d) capable of executing the second operation, and the second utilization unit (40a, 40b). In this case, the display unit (80) does not display the first item (141) for executing the first operation as the setting item (120), or displays it in a non-selectable manner. Air conditioner. In the air conditioner according to any one of claims 4 to 7.
Further, an operation unit (C3) for receiving an operation for executing the first operation or the second operation is provided.
The operation unit (C3) has a display unit (80) for displaying setting items (120) related to the first operation and the second operation.
As the utilization unit (40), at least one of the third utilization unit (40c) and the second utilization unit (40a, 40b), which are the first utilization units (40c, 40d) capable of executing the second operation. And the fourth utilization unit (40d) which is the first utilization unit (40c, 40d) in which the second operation cannot be executed, the display unit (80) sets the setting item (120). An air conditioner characterized by not displaying or displaying non-selectable. A refrigerant circuit (11) that includes a compressor (21), at least one heat source heat exchanger (22), a decompression mechanism (23) and at least one utilization heat exchanger (53) to perform a refrigeration cycle.
At least one heat source unit (20) provided with the heat source heat exchanger (22) and
At least one utilization unit (40) provided with the utilization heat exchanger (53) and
A control device (C) for controlling the heat source unit (20) and the utilization unit (40) so as to execute the first operation is provided.
The first operation is an operation including a first operation of performing a first refrigeration cycle using the utilization heat exchanger as an evaporator to generate dew condensation water or ice in the utilization heat exchanger (53).
The refrigerant circuit (11), at least one heat source unit (20) and at least one utilization unit (40) constitute one air conditioning unit (15).
A plurality of the air conditioning units (15) are provided.
The control device (C) includes a first heat source unit (20r) in which the heat source unit (20) can not execute the first operation in each of the plurality of air conditioning units (15), or the utilization unit ( The air conditioning unit (40c, 40d) having the first heat source unit (20r) or the first utilization unit (40c, 40d) when the 40) includes the first utilization unit (40c, 40d) incapable of performing the first operation. 15) An air conditioner comprising limiting the execution of the first operation. In the air conditioner according to any one of claims 4 to 8, the air conditioner
The refrigerant circuit (11), at least one heat source unit (20) and at least one utilization unit (40) constitute one air conditioning unit (15).
A plurality of the air conditioning units (15) are provided.
Further, an operation unit (C3) for receiving an operation for causing the plurality of air conditioning units (15) to execute the first operation or the second operation is further provided.
The operation unit (C3) has a display unit (80) for displaying setting items (120) related to the first operation and the second operation.
When the at least one air-conditioning unit (15) is the first air-conditioning unit (15x) that is allowed to execute the first operation, the display unit (80) sets the first operation as the setting item (120). An air conditioner characterized in that a first item (141) for executing one operation and a second item (142) for executing the second operation are selectively displayed. In the air conditioner according to any one of claims 1 to 10.
Further provided with an operation unit (C3) for receiving an operation for executing the first operation.
The operation unit (C3) has information capable of identifying whether or not the heat source unit (20) is the first heat source unit (20r), and / or the utilization unit (40) is the first utilization unit (20r). An air conditioner having a display unit (80) for displaying information that can identify whether or not it is 40c, 40d).

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