JP6925461B2 - Air conditioners, air conditioners and programs - Google Patents

Description

The present disclosure relates to air conditioners, air conditioners and programs.

An air conditioner that performs cooling operation usually circulates a refrigerant through a compressor, an outdoor heat exchanger, a decompressor, and an indoor heat exchanger to exchange heat between indoors and outdoors. The outdoor heat exchanger functions as a condenser to dissipate heat, and the indoor heat exchanger functions as an evaporator to absorb heat.

In addition to the above-mentioned cooling operation, an air conditioner that performs so-called reheat dehumidification is known (see, for example, Patent Document 1). Reheat dehumidification means an operation in which air is cooled below the dew point temperature to dehumidify and the air is heated at the same time.

The air conditioner described in Patent Document 1 is provided with a first heat exchanger and a second heat exchanger as indoor heat exchangers, and an electron is provided between the first heat exchanger and the second heat exchanger. An expansion valve is provided. Then, this air conditioner controls the throttle of the electronic expansion valve to dissipate heat by using the first heat exchanger as a reheater and absorbs heat by using the second heat exchanger as an evaporator to perform reheat dehumidification. conduct.

Japanese Unexamined Patent Publication No. 5-18630

When the air conditioner described in Patent Document 1 is in cooling operation, the refrigerant temperature of the first heat exchanger is maintained at a temperature somewhat lower than the room temperature of the air-conditioned space. As a result, the first heat exchanger cools the air. On the other hand, when the air conditioner is performing reheat dehumidification, the refrigerant temperature of the first heat exchanger is maintained at a temperature higher than room temperature to some extent. Therefore, when the air conditioner switches from the cooling operation to the reheat dehumidification operation, the refrigerant temperature of the first heat exchanger rises discontinuously. Therefore, the ability of the air conditioner to handle the sensible heat load also fluctuates discontinuously, which may impair user comfort.

The present disclosure has been made in view of the above circumstances, and an object of the present disclosure is to improve user comfort.

In order to achieve the above object, the air conditioner of the present disclosure is an air conditioner that operates in an operation mode selected from a first cooling mode, a second cooling mode, and a dehumidification mode, and is a compressor, an outdoor heat exchanger, and the like. A refrigerant circuit that circulates refrigerant through the first expansion valve, the first indoor heat exchanger, the second expansion valve, and the second indoor heat exchanger in this order, and temperature information indicating the temperature of air in the indoor space to be air-conditioned. , and includes an acquisition unit configured to acquire weather information, and the indoor air blowing means for blowing air heat-exchanged by the first indoor heat exchanger and the second indoor heat exchanger within the chamber space, the first cooling mode Then, the refrigerant evaporation temperature of the first chamber heat exchanger becomes equal to the refrigerant evaporation temperature of the second chamber heat exchanger, and in the second cooling mode, the refrigerant evaporation temperature of the first chamber heat exchanger is the second chamber heat exchange. It is higher than the refrigerant evaporation temperature of the vessel and lower than the temperature indicated by the temperature information, and in the dehumidification mode, the refrigerant evaporation temperature of the first chamber heat exchanger is higher than the temperature indicated by the temperature information, and the operation mode is predetermined. When the above conditions are satisfied according to the weather information, one of the first cooling mode, the second cooling mode, and the dehumidifying mode shifts to the other mode, and the operation mode that shifts from the first cooling mode is the first. 2 The cooling mode, the operation mode for shifting from the second cooling mode is the first cooling mode or the dehumidifying mode, and the operation mode for shifting from the dehumidifying mode is the second cooling mode .

According to the present disclosure, the comfort of the user can be improved.

The figure which shows the structure of the air conditioner which concerns on Embodiment 1. The figure which shows the relationship between the sensible heat load and the opening degree of an expansion valve The figure which shows the relationship between the sensible heat load and the refrigerant evaporation temperature. Flow diagram showing air conditioning processing The figure which shows the example of the transition of the outside air temperature, the room temperature and the opening degree of an expansion valve. The figure which shows the relationship between the sensible heat capacity and the latent heat capacity which concerns on Embodiment 1. The figure which shows the example of the transition of the outside air temperature, the room temperature and the air volume of the outdoor blower which concerns on Embodiment 2. The figure which shows the structure of the air conditioner which concerns on Embodiment 3. The figure which shows the structure of the air conditioner which concerns on Embodiment 4. The figure which shows the relationship between the sensible heat capacity and the latent heat capacity which concerns on Embodiment 5.

Hereinafter, embodiments of the present disclosure will be described in detail with reference to the drawings.

Embodiment 1.
FIG. 1 shows the configuration of the air conditioner 100 according to the first embodiment. The air conditioner 100 is a room air conditioner that harmonizes the air in the indoor space to be air-conditioned by a vapor compression type heat pump. An interior space is a specific room in a building such as a house, office or factory. The air conditioner 100 performs a cooling operation that lowers the room temperature of the indoor space to a set temperature, a so-called reheat dehumidification operation that lowers the humidity of the indoor space, and a heating that raises the room temperature of the indoor space to a set temperature. The operations are performed and these operations harmonize the air in the room space. The air conditioning device 100 enhances the comfort of the user in the indoor space by smoothly changing the temperature of the conditioned air when switching between the cooling operation and the dehumidifying operation.

As shown in FIG. 1, the air conditioner 100 has an outdoor unit 110 and an indoor unit 120 connected by a refrigerant pipe 101. In FIG. 1, the refrigerant pipe 101 is shown by a thick solid line.

The refrigerant pipe 101 includes a copper pipe for circulating the refrigerant between the outdoor unit 110 and the indoor unit 120, and a protective member for preventing corrosion of the copper pipe and absorption and heat dissipation of the refrigerant. The refrigerant pipe 101 includes a tube and a pipe. The refrigerant is, for example, R410A or R32, which is an HFC (Hydro Fluoro Carbons) refrigerant. However, the material of the refrigerant pipe and the type of the refrigerant are not limited to this, and are arbitrary.

The outdoor unit 110 is installed outdoors such as a wall surface or a rooftop of a building having an indoor space inside. The outdoor unit 110 includes a compressor 111 that compresses the refrigerant, a four-way valve 112 that switches the flow path of the refrigerant, an outdoor heat exchanger 113 that exchanges heat between the outside air and the refrigerant, and air in the outdoor heat exchanger 113. It has an outdoor blower 114 for blowing air, and a first expansion valve 115 having a variable opening degree. The compressor 111, the four-way valve 112, the outdoor heat exchanger 113, and the first expansion valve 115 are connected by a refrigerant pipe 101.

The compressor 111 is, for example, a scroll compressor, a rotary compressor, or other device that compresses the refrigerant by a method. The compressor 111 compresses the refrigerant vapor that has flowed from the four-way valve 112 into the suction port via the refrigerant pipe 101, and discharges the high-temperature and high-pressure refrigerant vapor from the discharge port. The refrigerant vapor discharged by the compressor 111 is sent to the four-way valve 112 via the refrigerant pipe 101. The compressor 111 operates according to a control signal transmitted from the control unit 129 of the indoor unit 120, and the operating frequency of the compressor 111 is specified by this control signal.

The four-way valve 112 is connected to the suction port and the discharge port of the compressor 111 via the refrigerant pipe 101. Further, the four-way valve 112 is connected to the outdoor heat exchanger 113 and the second indoor heat exchanger 122 of the indoor unit 120 via the refrigerant pipe 101. The four-way valve 112 switches the flow path of the refrigerant according to the control signal transmitted from the control unit 129. That is, the four-way valve 112 sends the refrigerant delivered from the discharge port of the compressor 111 to the outdoor heat exchanger 113 or the second indoor heat exchanger 122. Further, the four-way valve 112 delivers the refrigerant delivered from the outdoor heat exchanger 113 or the second indoor heat exchanger 122 to the suction port of the compressor 111. By switching the flow path of the four-way valve 112, either the refrigerant circuit 102 for the cooling operation and the dehumidifying operation and the refrigerant circuit 102 for the heating operation are formed. Details of the refrigerant circuit 102 will be described later.

The outdoor heat exchanger 113 is connected to the four-way valve 112 and the first expansion valve 115 via the refrigerant pipe 101, and sends out the refrigerant flowing from one of the four-way valve 112 and the first expansion valve 115 to the other. The outdoor heat exchanger 113 condenses or evaporates the inflowing refrigerant by exchanging heat between the outside air and the refrigerant, and discharges the liquefied refrigerant or the refrigerant vapor. For example, during the cooling operation or the dehumidifying operation, the outdoor heat exchanger 113 functions as a condenser to dissipate heat from the refrigerant. Further, during the heating operation, the outdoor heat exchanger 113 functions as an evaporator, so that the refrigerant absorbs heat.

The outdoor blower 114 includes a fan and an electric motor for rotating the fan, and is arranged in the vicinity of the outdoor heat exchanger 113. The outdoor blower 114 rotates the fan according to the control signal transmitted from the control unit 129 to generate an air flow that flows in from the outside of the outdoor unit 110 and passes through the outdoor heat exchanger 113. The air heat exchanged by the outdoor heat exchanger 113 is heated or cooled and discharged to the outside of the outdoor unit 110. The air volume of the outdoor blower 114 is specified by a control signal from the control unit 129.

The first expansion valve 115 is a decompressor whose opening degree can be continuously changed by a built-in pulse motor. The first expansion valve 115 is connected to the outdoor heat exchanger 113 and the first indoor heat exchanger 121 of the indoor unit 120 via the refrigerant pipe 101, and is connected from one of the outdoor heat exchanger 113 and the first indoor heat exchanger 121. The inflowing refrigerant is sent to the other. The first expansion valve 115 reduces the pressure applied to the inflowing refrigerant to expand the refrigerant, and discharges the refrigerant having a lower temperature and lower pressure than the inflowing refrigerant. The temperature and pressure of the refrigerant discharged from the first expansion valve 115 change according to the opening degree of the first expansion valve 115. However, if the opening degree of the first expansion valve 115 is fully opened, the refrigerant passes through the first expansion valve 115 without being depressurized and substantially expanding. The opening degree of the first expansion valve 115 is specified by the number of pulses of the control signal transmitted from the control unit 129. The opening degree corresponds to the throttle amount, and the fully opened opening degree corresponds to the state where the throttle amount is zero.

The indoor unit 120 is installed, for example, on a wall or ceiling of an indoor space, and harmonizes the air in the indoor space by blowing out cold air or hot air. The indoor unit 120 includes a first indoor heat exchanger 121 and a second indoor heat exchanger 122 that exchange heat between air and a refrigerant in the indoor space, and a first indoor heat exchanger 121 and a second indoor heat exchanger. The air exchanged by the second expansion valve 123 having a variable opening degree arranged in the refrigerant pipe 101 between the 122 and the first chamber heat exchanger 121 and the second chamber heat exchanger 122 is blown into the indoor space. The indoor blower 124, the sensor 121a for measuring the refrigerant evaporation temperature of the first indoor heat exchanger 121, the sensor 122a for measuring the refrigerant evaporation temperature of the second indoor heat exchanger 122, and the air temperature in the indoor space are measured. The sensor 125a, the sensor 126a that measures the humidity of the air in the indoor space, the sensor 127a that receives infrared rays, the acquisition unit 128 that acquires information indicating the measurement result from each sensor, and each component of the air conditioner 100. It has a control unit 129 for controlling. The first chamber heat exchanger 121, the second expansion valve 123, and the second chamber heat exchanger 122 are connected in this order by the refrigerant pipe 101. In FIG. 1, the broken line connected to the acquisition unit 128 and the broken line connected to the control unit 129 indicate a signal line.

The first indoor heat exchanger 121 is connected to the first expansion valve 115 and the second expansion valve 123 via the refrigerant pipe 101, and the refrigerant flowing in from one of the first expansion valve 115 and the second expansion valve 123 is sent to the other. Send out. Further, the second chamber heat exchanger 122 is connected to the second expansion valve 123 and the four-way valve 112 via the refrigerant pipe 101, and sends out the refrigerant flowing from one of the second expansion valve 123 and the four-way valve 112 to the other. ..

The first indoor heat exchanger 121 and the second indoor heat exchanger 122 exchange heat between the air in the indoor space and the refrigerant to evaporate or condense the inflowing refrigerant, resulting in refrigerant vapor, liquefied refrigerant, or Discharge the two-phase refrigerant. The two-phase refrigerant means a refrigerant in which refrigerant vapor and liquefied refrigerant are mixed. For example, during the cooling operation, the first indoor heat exchanger 121 and the second indoor heat exchanger 122 function as evaporators to absorb heat from the refrigerant and cool the air in the indoor space. Further, during the heating operation, the first indoor heat exchanger 121 and the second indoor heat exchanger 122 function as condensers to dissipate heat from the refrigerant and heat the air in the indoor space. However, during the dehumidifying operation, the first chamber heat exchanger 121 functions as a condenser to heat the air, and the second chamber heat exchanger 122 functions as an evaporator to cool the air below the dew point temperature. Is dehumidified.

The second expansion valve 123 is a decompressor having the same configuration as the first expansion valve 115. However, the size, shape and material of the members constituting the second expansion valve 123 may be different from those of the first expansion valve 115. The second expansion valve 123 is connected to the first chamber heat exchanger 121 and the second chamber heat exchanger 122 via the refrigerant pipe 101, and is connected to the first chamber heat exchanger 121 and the second chamber heat exchanger 122 from one of the first chamber heat exchanger 121 and the second chamber heat exchanger 122. The inflowing refrigerant is decompressed and sent to the other. The opening degree of the first expansion valve 115 is specified by a control signal transmitted from the control unit 129.

The indoor blower 124 has the same configuration as the outdoor blower 114, and is arranged in the vicinity of the first indoor heat exchanger 121 and the second indoor heat exchanger 122. However, the fan of the indoor blower 124 is, for example, a cross flow fan or a propeller fan. The indoor blower 124 flows into the indoor unit 120 from the indoor space by rotating the fan according to the control signal transmitted from the control unit 129, and causes the first indoor heat exchanger 121 and the second indoor heat exchanger 122 to flow into the indoor unit 120. Generates an air flow that passes through. The air heat exchanged by the first indoor heat exchanger 121 and the second indoor heat exchanger 122 is cooled or heated and blown into the indoor space from the outlet of the indoor unit 120. The wind direction and air volume of the indoor blower 124 are specified by a control signal from the control unit 129.

Note that, for convenience, FIG. 1 shows a fan and a motor having one rotating shaft as the indoor blower 124, but the present invention is not limited to this. The indoor blower 124 may have a fan and a motor for blowing air to the first indoor heat exchanger 121 and a fan and a motor for blowing air to the second indoor heat exchanger 122, respectively. Further, FIG. 1 shows a state in which an air flow passing through the first chamber heat exchanger 121 and an air flow passing through the second chamber heat exchanger 122 are generated, but the present invention is not limited to this. .. The indoor blower 124 may generate an air flow that passes through both the first indoor heat exchanger 121 and the second indoor heat exchanger 122 in this order or in the reverse order.

The sensor 121a is arranged in the central portion of the first chamber heat exchanger 121. The sensor 121a measures the temperature of the pipes constituting the first indoor heat exchanger 121 as the refrigerant evaporation temperature in the first indoor heat exchanger 121, and transmits the temperature information indicating the measurement result to the acquisition unit 128. The sensor 121a may measure the temperature of the refrigerant pipe 101 in the vicinity of the suction port or the discharge port of the first indoor heat exchanger 121 as the refrigerant evaporation temperature of the first indoor heat exchanger 121.

The sensor 122a is arranged in the central portion of the second chamber heat exchanger 122. The sensor 122a measures the temperature of the pipes constituting the second chamber heat exchanger 122 as the refrigerant evaporation temperature in the second chamber heat exchanger 122, and transmits the temperature information indicating the measurement result to the acquisition unit 128. The sensor 122a may measure the temperature of the refrigerant pipe 101 in the vicinity of the suction port or the discharge port of the first indoor heat exchanger 121 as the refrigerant evaporation temperature of the second indoor heat exchanger 122.

It is desirable, but not limited to, that the sensors 121a and 122a directly measure the actual refrigerant evaporation temperature. The temperature measured by the sensors 121a and 122a may be such that the control unit 129 can estimate the refrigerant evaporation temperature to some extent from the measurement result.

The sensors 125a and 126a are arranged in the vicinity of the air suction port of the indoor unit 120. The sensors 125a and 126a measure the temperature and humidity of the air sucked into the indoor unit 120 as the temperature and humidity of the air in the indoor space, respectively, and transmit the temperature information and the humidity information indicating the measurement results to the acquisition unit 128.

The sensor 127a is composed of an element that detects infrared rays, such as a thermopile or a bolometer. The sensor 127a is used to measure the temperature distribution in the indoor space.

The acquisition unit 128 includes an interface circuit for acquiring information such as measurement results from each sensor. The acquisition unit 128 acquires temperature information indicating the refrigerant evaporation temperature of the first indoor heat exchanger 121 and the second indoor heat exchanger 122 from the sensors 121a and 122a, and the temperature and humidity of the air in the indoor space from the sensors 125a and 126a. The temperature information and the humidity information indicating the above are acquired, and the data transmitted from the terminal 140 is acquired. Then, the acquisition unit 128 transmits the acquired information to the control unit 129.

The control unit 129 includes a microprocessor, a RAM (Random Access Memory), and an EEPROM (Electrically Erasable Programmable Read-Only Memory). When the microprocessor constituting the control unit 129 executes the program P1 stored in the EEPROM, the control unit 129 exerts various functions. That is, the control unit 129 has the operating frequency of the compressor 111, the flow path of the four-way valve 112, the air volume of the outdoor blower 114, the opening degree of the first expansion valve 115, and the second expansion based on the information received from the acquisition unit 128. The opening degree of the valve 123 and the air volume of the indoor blower 124 are appropriately controlled. By controlling each component of the air conditioner 100 by the control unit 129, the cooling operation, the dehumidifying operation, and the heating operation of the air conditioner 100 are executed.

The terminal 140 is a remote control terminal for the user to operate the air conditioner 100. The terminal 140 may be a smartphone or a wearable terminal. The terminal 140 acquires data indicating the operation mode and the set temperature input from the user, and transmits a wireless signal typified by infrared rays or a wireless LAN indicating the data to the air conditioner 100.

In the air conditioner 100 having the above configuration, the refrigerant circuit 102 when the cooling operation and the dehumidifying operation are executed includes the compressor 111, the four-way valve 112, the outdoor heat exchanger 113, and the first refrigerant circuit 102, as shown in FIG. 1 The expansion valve 115, the first chamber heat exchanger 121, the second expansion valve 123, the second chamber heat exchanger 122 and the four-way valve 112 are passed in this order to circulate the refrigerant. In FIG. 1, the direction in which the refrigerant flows in the refrigerant circuit 102 is indicated by a solid arrow. Further, the refrigerant circuit 102 when the heating operation is executed includes a compressor 111, a four-way valve 112, a second indoor heat exchanger 122, a second expansion valve 123, a first indoor heat exchanger 121, and a first expansion valve 115. , The outdoor heat exchanger 113 and the four-way valve 112 are passed in this order to circulate the refrigerant. In FIG. 1, the direction in which the refrigerant flows in the refrigerant circuit 102 is indicated by a broken line arrow.

Subsequently, each operation mode of the air conditioner 100 will be described. The operation mode according to the present embodiment includes a first cooling mode, a second cooling mode, a third cooling mode, a dehumidifying mode, and a heating mode. The first cooling mode, the second cooling mode, and the third cooling mode correspond to the cooling operation of the air conditioner 100, the dehumidification mode corresponds to the dehumidification operation of the air conditioner 100, and the heating mode corresponds to the air conditioner 100. Corresponds to the heating operation of. The air conditioning device 100 selects one operation mode from these plurality of operation modes and operates in the selected operation mode to blow conditioned air into the indoor space.

The operation mode means a specific state in which the air conditioner 100 is continuously operated. Normally, the air conditioner 100 continues to operate according to one operation mode unless the information acquired by the acquisition unit 128 changes. Here, the continuation of operation means that the operation mode does not change for at least one minute.

In the present embodiment, the control unit 129 controls the opening degrees of the first expansion valve 115 and the second expansion valve 123 according to the sensible heat load, and changes the operation mode according to predetermined conditions. The sensible heat load means the energy required to change the temperature of the indoor space to the set temperature. The control unit 129 changes the operation mode in the order of the first cooling mode, the second cooling mode, the third cooling mode, and the dehumidifying mode when it is necessary to cool the indoor space having a large sensible heat load. In the following, the case of changing the operation mode in this way will be mainly described.

FIG. 2 shows the relationship between the sensible heat load and the opening degrees of the first expansion valve 115 and the second expansion valve 123 controlled by the control unit 129. The line L1 in FIG. 2 indicates the opening degree of the first expansion valve, and the line L2 indicates the opening degree of the second expansion valve.

As a result of controlling the opening degree of the expansion valve as shown in FIG. 2, the refrigerant evaporation temperatures of the first chamber heat exchanger 121 and the second chamber heat exchanger 122 are shown in FIG. 3 according to the sensible heat load. It changes like this. The line L11 in FIG. 3 shows the refrigerant evaporation temperature of the first chamber heat exchanger 121, and the line L12 shows the refrigerant evaporation temperature of the second chamber heat exchanger 122. Here, the first cooling mode, the second cooling mode, the third cooling mode, and the dehumidification mode are as follows from the relationship between the refrigerant evaporation temperature and the current room temperature Tr indicated by the temperature information acquired by the acquisition unit 128. Is stipulated in.

The first cooling mode is an operation mode in which the refrigerant evaporation temperature of the first chamber heat exchanger 121 becomes equal to the refrigerant evaporation temperature of the second chamber heat exchanger 122. The first cooling mode is realized by the control unit 129 setting the opening degree of the first expansion valve 115 and the second expansion valve 123 to a predetermined opening degree. Specifically, as shown in FIG. 2, the control unit 129 narrows the opening degree of the first expansion valve 115 and fully opens the opening degree of the second expansion valve 123 to execute the operation in the first cooling mode. Will be done. In the first cooling mode, the low-temperature low-pressure refrigerant discharged from the first expansion valve 115 evaporates in the first indoor heat exchanger 121 and the second indoor heat exchanger 122, and the indoor unit 120 cools the air in the indoor space. Blow to.

The second cooling mode is an operation mode in which the refrigerant evaporation temperature of the first chamber heat exchanger 121 is equal to or higher than the refrigerant evaporation temperature of the second chamber heat exchanger 122 and becomes room temperature Tr or lower. In the second cooling mode, as shown in FIG. 2, the control unit 129 opens the opening degree of the first expansion valve 115 from the opening degree in the first cooling mode, and sets the opening degree of the second expansion valve 123 to the first. It is realized by narrowing down from the opening in the cooling mode. In the second cooling mode, the medium-temperature and medium-pressure refrigerant decompressed by the first expansion valve 115 evaporates in the first chamber heat exchanger 121 and is depressurized again in the second expansion valve 123. The low-temperature low-pressure refrigerant discharged from the second expansion valve 123 evaporates in the second chamber heat exchanger 122. Then, the indoor unit 120 blows air cooled weaker than in the first cooling mode into the indoor space.

The third cooling mode is an operation mode in which the refrigerant evaporation temperature of the first chamber heat exchanger 121 becomes equal to the room temperature Tr. The third cooling mode is realized by the control unit 129 adjusting the opening degree of the first expansion valve 115 and the second expansion valve 123 as shown in FIG. Specifically, the control unit 129 sets the opening degree of the first expansion valve 115 as the maximum opening degree in the second cooling mode and the opening degree of the second expansion valve 123 as the minimum opening degree in the second cooling mode. Then, the operation of the third cooling mode is executed. In the third cooling mode, the temperature of the refrigerant decompressed by the first expansion valve 115 is equal to the room temperature Tr, so that the first chamber heat exchanger 121 does not exchange heat. The refrigerant that has passed through the first chamber heat exchanger 121 without condensing or evaporating is depressurized again by the second expansion valve 123, and the low-temperature low-pressure refrigerant evaporates in the second chamber heat exchanger 122. Then, the indoor unit 120 blows the air cooled only by the second indoor heat exchanger 122 into the indoor space without being cooled by the first indoor heat exchanger 121.

The third cooling mode is included in the second cooling mode. However, the second cooling mode is different from the third cooling mode as an operation mode in which the refrigerant evaporation temperature of the first chamber heat exchanger 121 is higher than the refrigerant evaporation temperature of the second chamber heat exchanger 122 and lower than the room temperature Tr. It may be an operation mode.

The dehumidification mode is an operation mode in which the refrigerant evaporation temperature of the first chamber heat exchanger 121 is higher than the room temperature Tr. In the dehumidification mode, as shown in FIG. 2, the control unit 129 opens the opening degree of the first expansion valve 115 from the opening degree in the third cooling mode, and opens the opening degree of the second expansion valve 123 in the third cooling mode. It is realized by narrowing down from the opening in. In the dehumidification mode, the refrigerant slightly depressurized by the first expansion valve 115 or the refrigerant that has passed through the first expansion valve 115 without being depressurized is condensed in the first chamber heat exchanger 121 and is condensed in the second expansion valve 123. The pressure is reduced. The low-temperature low-pressure refrigerant discharged from the second expansion valve 123 evaporates in the second chamber heat exchanger 122. Then, the indoor unit 120 is heated by the first indoor heat exchanger 121, cooled to a dew point temperature or lower by the second indoor heat exchanger 122, and dehumidified air is blown into the indoor space.

Subsequently, the air conditioning process performed by the air conditioning device 100 will be described with reference to FIG. The air conditioning process shown in FIG. 4 starts when the power of the air conditioning device 100 is turned on.

When the air conditioning process starts, the acquisition unit 128 acquires the information (step S1). This information includes temperature information and humidity information indicating the measurement results of each sensor, and when the user operates the terminal, includes at least one of the set temperature and the operation mode specified by the user.

Next, the control unit 129 determines whether or not the operation mode is specified (step S2). When it is determined that the operation mode has been specified (step S2; Yes), the control unit 129 controls the opening degrees of the first expansion valve 115 and the second expansion valve 123 as shown in FIG. Operate in the operation mode (step S3). Specifically, the control unit 129 selects a designated operation mode and controls each component of the air conditioner 100 including the expansion valve according to the selected operation mode to harmonize the air in the indoor space. As a result, the indoor blower 124 blows conditioned air into the indoor space.

When the set temperature is not set, the control unit 129 may use a predetermined target value as the set temperature. This target value is, for example, a value of 22 ° C. previously recorded in EEPROM, or a value determined according to the outside air temperature.

Further, the control unit 129 may control the opening degree of the expansion valve as shown in FIG. 2 simply according to the sensible heat load, but the present invention is not limited to this. The control unit 129 controls the opening degree of the expansion valve by feedback control using the measurement results of the sensors 121a and 122a so that the refrigerant evaporation temperature determined according to the sensible heat load is realized as shown in FIG. You may.

When this feedback control is performed, if the measurement result of the sensor 121a is higher than the refrigerant evaporation temperature as the target value shown in FIG. 3, the control unit 129 slightly closes the first expansion valve 115, and the measurement result is obtained. If it is lower than the target value, the first expansion valve 115 is opened slightly. Further, the control unit 129 slightly opens the second expansion valve 123 if the measurement result of the sensor 122a is lower than the refrigerant evaporation temperature as the target value shown in FIG. 3, and the second expansion if the measurement result is higher than the target value. Slightly close valve 123.

If such feedback control is performed, the control unit 129 accurately controls the refrigerant evaporation temperature, and the sensible heat capacity of the air conditioner 100 is accurately realized as designed. The sensible heat capacity is a general term including the cooling capacity during the cooling operation and the cooling capacity during the dehumidifying operation, and means the capacity of the sensible heat load processed by the air conditioner 100. As a result, the temperature of the indoor space is stabilized, which in turn improves the comfort of the user. Further, since the refrigerant evaporation temperature is appropriately controlled, it is possible to prevent the compressor 111 from inhaling the liquid refrigerant and failing.

After returning to FIG. 4 and executing step S3, the control unit 129 shifts the process to step S7.

On the other hand, when it is determined that the operation mode is not specified (step S2; No), the control unit 129 determines whether or not the set temperature is specified (step S4). When it is determined that the set temperature is specified (step S4; Yes), the control unit 129 shifts the process to step S6.

On the other hand, when it is determined that the set temperature is not specified (step S4; No), the control unit 129 designates a predetermined target value as the set temperature (step S5).

Next, the control unit 129 controls the opening degrees of the first expansion valve 115 and the second expansion valve 123 as shown in FIG. 2 and operates in an operation mode according to the current sensible heat load (step S6). ). As a result, the indoor blower 124 blows conditioned air into the indoor space.

Next, the control unit 129 acquires information from the acquisition unit 128 (step S7). This information includes temperature information and humidity information indicating the measurement results of each sensor.

Next, the control unit 129 determines whether or not the operation mode transition condition is satisfied (step S8). The operation mode transition conditions differ depending on the current operation mode and the operation mode after the transition. This transition condition is predetermined and stored in the EEPROM of the control unit 129. The transition conditions are the current room temperature indicated by the temperature information acquired by the acquisition unit 128, the humidity of the current indoor space indicated by the humidity information acquired by the acquisition unit 128, the operating frequency of the compressor 111, and the current operation. It is established according to the duration of operation according to the mode.

For example, the conditions for shifting the operation mode from the first cooling mode to the second cooling mode are that the current room temperature is lower than the first threshold value, the humidity of the current indoor space is higher than the second threshold value, and the operating frequency of the compressor 111 is high. It is lower than the third threshold value, and the operation according to the first cooling mode is continued for 1 minute or more. Further, the conditions for shifting the operation mode from the second cooling mode including the third cooling mode to the dehumidification mode are that the current room temperature is lower than the fourth threshold value, the humidity of the current indoor space is higher than the fifth threshold value, and the compressor 111. The operating frequency of the above is lower than the sixth threshold value, and the operation according to the second cooling mode is continued for one minute or more.

The first threshold value and the fourth threshold value may be predetermined values such as 26 ° C. and 28 ° C. recorded in EEPROM, or may be values obtained by adding a predetermined margin to the set temperature. .. The second threshold value and the fifth threshold value are, for example, predetermined values recorded in EEPROM, set temperature, or values determined according to the set humidity. The third threshold value and the sixth threshold value are, for example, a predetermined value recorded in EEPROM or a value obtained by adding a predetermined margin to the minimum operating frequency when the compressor 111 operates. The first threshold value and the fourth threshold value may be different values, the second threshold value and the fifth threshold value may be different values, and the third threshold value and the sixth threshold value may be different values.

However, the operation mode shifts in the order of the first cooling mode, the second cooling mode, the third cooling mode, and the dehumidification mode, or in the reverse order. That is, the control unit 129 shifts the operation mode from one mode to another when the shift condition is satisfied. At this time, the operation mode for shifting from the first cooling mode is the second cooling mode, and the operation mode does not shift from the first cooling mode to the third cooling mode or the dehumidification mode. The operation mode for shifting from the second cooling mode is the first cooling mode or the dehumidifying mode. When a specific condition is satisfied in the second cooling mode, the operation mode shifts to the third cooling mode. The operation mode for shifting from the third cooling mode is the second cooling mode or the dehumidifying mode, and the operation mode does not shift from the third cooling mode to the first cooling mode. Further, the operation mode for shifting from the dehumidification mode is the second cooling mode or the third cooling mode, and the operation mode does not shift from the dehumidification mode to the first cooling mode.

When it is determined that the operation mode transition condition is not satisfied (step S8; No), the control unit 129 shifts the process to step S10. On the other hand, when it is determined that the operation mode transition condition is satisfied (step S8; Yes), the control unit 129 shifts the operation mode according to the satisfied transition condition (step S9). Specifically, the control unit 129 selects an operation mode different from the currently selected operation mode according to the transition condition.

Next, the control unit 129 controls the opening degrees of the first expansion valve 115 and the second expansion valve 123 as shown in FIG. 2 and operates in the current operation mode (step S10). As a result, the indoor blower 124 blows conditioned air into the indoor space. After that, the control unit 129 repeats the processes after step S7.

Subsequently, an example of the transition of the operation mode realized by the above air conditioning process will be described with reference to FIG. FIG. 5 shows changes in the outside air temperature, room temperature, and opening degree of the expansion valve when the cooling operation and the dehumidifying operation are executed on a summer day on a common time axis.

As shown in FIG. 5, since the outside air temperature is high and the sensible heat load of cooling is large in the daytime, the air conditioner 100 operates in the first cooling mode to cool the indoor space. As the outside air temperature gradually decreases from noon to evening, the sensible heat load also gradually decreases. When the room temperature drops to the vicinity of the set temperature, the control unit 129 lowers the operating frequency of the compressor 111 to reduce the cooling capacity. However, since the compressor 111 needs to be operated at a minimum operating frequency or higher, the room temperature will drop below the set temperature even if the compressor 111 is operated at this minimum operating frequency.

Here, when the condition for shifting the operation mode from the first cooling mode to the second cooling mode is satisfied, the control unit 129 switches the operation mode to the second cooling mode. Since the cooling capacity of the air conditioner 100 is smaller in the second cooling mode than in the first cooling mode, the room temperature rises slightly when the operation mode is switched. As a result, the room temperature can be maintained in the vicinity of the set temperature. Further, since the latent heat capacity of the air conditioner 100 increases, the air conditioner 100 can also perform dehumidification. The latent heat capacity corresponds to the dehumidifying capacity and means the capacity of the latent heat load in the indoor space processed by the air conditioner 100.

As the outside air temperature drops from evening to night, the sensible heat load also gradually decreases. When the room temperature drops to the vicinity of the set temperature, the control unit 129 lowers the operating frequency of the compressor 111, but the room temperature drops to the set temperature or lower again. Here, when the condition for shifting the operation mode to the third cooling mode is satisfied, the control unit 129 switches the operation mode to the third cooling mode. When the mode is switched to the third cooling mode, the sensible heat capacity of the air conditioner 100 becomes smaller, so that the room temperature rises slightly. As a result, the room temperature can be maintained in the vicinity of the set temperature. Further, since the latent heat capacity of the air conditioner 100 increases, the air conditioner 100 can also perform dehumidification.

When the outside temperature drops further at midnight, the sensible heat load also decreases. When the room temperature drops to the vicinity of the set temperature, the control unit 129 lowers the operating frequency of the compressor 111, but the room temperature drops below the set temperature. Here, when the condition for shifting the operation mode from the second cooling mode to the dehumidification mode is satisfied, the control unit 129 switches the operation mode to the dehumidification mode. Since the sensible heat capacity of the air conditioner 100 is smaller in the dehumidifying mode than in the second cooling mode, the room temperature rises slightly when the operation mode is switched. As a result, the room temperature can be maintained in the vicinity of the set temperature. Further, since the latent heat capacity of the air conditioner 100 increases, the air conditioner 100 can also perform dehumidification.

As described above, the air conditioner 100 according to the present embodiment executes the cooling operation in the first cooling mode, then the cooling operation in the second cooling mode, and performs the cooling operation in the second cooling mode. After that, the dehumidification operation in the dehumidification mode was executed.

Generally, there is known a method of maintaining the room temperature near the set temperature by stopping the compressor when the room temperature becomes lower than the set temperature and operating the compressor when the room temperature becomes higher than the set temperature. However, due to frequent stoppage and repeated operation of the compressor, the room temperature and air volume vibrate significantly at short time intervals, and dehumidification becomes difficult, which impairs user comfort. Further, if the number of times the compressor is started and stopped increases, the product life of the compressor may be shortened.

On the other hand, in the present embodiment, even if it becomes necessary to raise the room temperature during the cooling operation due to the restriction due to the minimum operating frequency of the compressor 111, the sensible heat capacity is not stopped without stopping the compressor 111. It is possible to keep the room temperature at the set temperature by reducing the size. That is, the comfort of the user can be improved and the reliability of the product can be improved without the compressor 111 starting and stopping frequently.

FIG. 6 shows the relationship between the sensible heat capacity and the latent heat capacity of the air conditioner 100. In the first cooling mode in FIG. 6, the sensible heat capacity increases as the operating frequency of the compressor 111 increases. The boundary between the first cooling mode and the second cooling mode corresponds to a state in which the compressor 111 is operated at the lowest operating frequency. In the present embodiment, as shown in FIG. 6, by changing the operation mode in the order of the first cooling mode, the second cooling mode, the third cooling mode and the dehumidification mode, or in the reverse order, the sensible heat capacity and The latent heat capacity can be adjusted continuously. Therefore, when the heat load is small, such as on a summer night or in the middle of spring, rainy season, or autumn in Japan, it is possible to finely adjust the temperature and humidity in the room, and the comfort of the user is improved.

Further, in the present embodiment, the operation modes are shifted in the order of the first cooling mode, the second cooling mode, the third cooling mode and the dehumidification mode, or in the reverse order. By transitioning the operation mode in this way, the air conditioner 100 can continuously control the sensible heat capacity and the latent heat capacity, and can suppress abrupt fluctuations in temperature and humidity in the indoor space. Further, since the operation mode changes as described above, as can be seen from FIG. 2, the opening degree of the expansion valve changes slowly and continuously. As a result, the generation of refrigerant noise can be suppressed as much as possible.

Further, the transition condition includes a condition that the operating frequency of the compressor 111 is equal to or less than the threshold value. If the operating frequency of the compressor 111 is small, the flow rate of the refrigerant is small, and the noise of the refrigerant generated when the operation mode is changed can be suppressed.

Further, the transition conditions according to the present embodiment include the measurement result of the temperature and humidity in the indoor space, the operating frequency of the compressor 111, and the duration of operation according to one operation mode. As a result, the control unit 129 changes the operation mode in consideration of the sensible heat load, the latent heat load, the total heat load, and the load fluctuation in the indoor space. Therefore, even if the sensible heat load and the latent heat load change due to the environmental change from day to night or the weather change from sunny to rain, the temperature and humidity of the indoor space are kept approximately constant, and the user's comfort is improved. improves.

Embodiment 2.
Subsequently, the second embodiment will be described focusing on the differences from the first embodiment described above. For the same or equivalent configuration as that of the first embodiment, the same reference numerals are used, and the description thereof will be omitted or simplified. The dehumidification mode according to the present embodiment is different from that according to the first embodiment in that it includes a first dehumidification mode and a second dehumidification mode in which the air volume of the outdoor blower 114 is smaller than the air volume in the first dehumidification mode. There is.

In the second dehumidification mode, the air volume of the outdoor blower 114 is smaller than that in the first dehumidification mode, so that the refrigerant evaporation temperatures of the outdoor heat exchanger 113 and the first indoor heat exchanger 121 rise. Therefore, the temperature of the air passing through the first chamber heat exchanger 121 is higher than that in the first dehumidification mode. Therefore, the sensible heat capacity is closer to zero than in the first dehumidification mode.

The operation mode according to the present embodiment shifts in the order of the first cooling mode, the second cooling mode, the third cooling mode, the first dehumidification mode and the second dehumidification mode, or in the reverse order. That is, the operation mode for shifting from the second cooling mode is the first cooling mode or the first dehumidification mode, and the operation mode does not shift from the second cooling mode to the second dehumidification mode. Further, the operation mode for shifting from the third cooling mode is the second cooling mode or the first dehumidification mode, and the operation mode does not shift from the third cooling mode to the second dehumidification mode. Further, the operation mode for shifting from the first dehumidification mode is the second cooling mode, the third cooling mode, or the second dehumidification mode, and the operation mode does not shift from the first dehumidification mode to the first cooling mode. Further, the operation mode for shifting from the second dehumidification mode is the first dehumidification mode, and the operation mode does not shift from the second dehumidification mode to the first cooling mode, the second cooling mode, or the third cooling mode.

FIG. 7 shows changes in the outside air temperature, the room temperature, and the air volume of the outdoor blower 114 when the cooling operation and the dehumidifying operation are executed on a summer day on a common time axis. As shown in FIG. 7, when the outside air temperature drops below room temperature from midnight to early morning, the cooling load becomes zero or a heating load occurs. However, even if the operation is continued in the first dehumidification mode, the room temperature drops below the set temperature due to the limitation of the operating frequency of the compressor 111.

Here, when a specific condition is satisfied, the control unit 129 changes the operation mode from the first dehumidification mode to the second dehumidification mode to reduce the air volume of the outdoor blower 114. In this condition, the room temperature acquired by the acquisition unit 128 is below the threshold value, the humidity of the indoor space acquired by the acquisition unit 128 is above the threshold value, the operating frequency of the compressor is below the threshold value, and the first The operation according to the dehumidification mode is continued for 1 minute or more. The threshold value for determining whether or not the condition is satisfied may be a predetermined value or may be determined according to the set temperature.

Since the sensible heat capacity of the air conditioner 100 is smaller in the second dehumidification mode than in the first dehumidification mode, the room temperature rises slightly when the operation mode is switched. As a result, the room temperature can be maintained in the vicinity of the set temperature. Further, since the latent heat capacity is maintained even when the operation mode is switched, the air conditioner 100 can also perform dehumidification.

As described above, the air conditioner 100 operates in the second dehumidification mode, which has a lower sensible heat capacity than the first dehumidification mode. Therefore, it is possible to adjust the temperature and humidity of the indoor space when the outside temperature is low but it is hot and humid due to rain, such as the rainy season in Japan. Further, since the sensible heat capacity in the second dehumidification mode is close to zero to some extent, it is possible to continuously shift the operation mode from the dehumidification operation to the heating operation. As a result, the comfort of the user is improved.

Embodiment 3.
Subsequently, the third embodiment will be described focusing on the differences from the first embodiment described above. For the same or equivalent configuration as that of the first embodiment, the same reference numerals are used, and the description thereof will be omitted or simplified. The transition condition according to the present embodiment is different from that according to the first embodiment in that it is satisfied according to the temperature of the building having the indoor space, the temperature and humidity of the outside air, and the body temperature of the user.

As shown in FIG. 8, the air conditioner 100 according to the present embodiment includes sensors 116a and 117a built in the outdoor unit to measure the temperature and humidity of the outside air, respectively, and sensors 150a to measure the temperature of the building. The terminal 140 has a body temperature detection unit 140a, which is a sensor for measuring the body temperature of the user. The acquisition unit 128 acquires temperature information and humidity information indicating the measurement results of each sensor, and notifies the control unit 129 of the temperature information and the humidity information. Then, the control unit 129 shifts the operation mode according to the measurement result indicated by the temperature information and the humidity information.

As described above, since the operation mode shifts according to the temperature of the building, the temperature and humidity of the outside air, and the body temperature of the user, it is possible to contribute to energy saving and improve the comfort of the user.

For example, when the outside air temperature drops sharply and the outside air humidity rises sharply while the user is sleeping, the control unit 129 assumes that the weather has changed from sunny to rain and operates. It is possible to switch modes quickly. Further, if the temperature and humidity of the outside air do not change even if the temperature and humidity in the room change, the control unit 129 determines that a temporary disturbance has occurred and determines not to change the operation mode. Is possible. As a result, the control unit 129 executes stable control, keeps the temperature and humidity of the indoor space constant, and improves user comfort.

The air conditioner 100 may be configured by omitting the sensors 116a and 117a, and the acquisition unit 128 may acquire weather information such as temperature and humidity of the outside air, solar radiation, and weather from a server device on the Internet.

Further, the sensor 150a may be omitted to form the air conditioner 100, and the control unit 129 may estimate the average radiation temperature or the amount of solar radiation from the skeleton surface temperature of the indoor space measured as the building temperature by the sensor 127a. Then, the control unit 129 may estimate the ratio of the sensible heat load and the latent heat load from the estimation result of the average radiant temperature and the like, and increase the air volume of the indoor blower 124 when the sensible heat load is large.

When the air volume of the indoor blower 124 increases, the sensible heat capacity increases and the latent heat capacity decreases. As a result, the heat load and the cooling capacity of the air conditioner 100 match. Therefore, it is possible to control the room temperature and relative humidity within a comfortable range. Further, since the pressure on the low pressure side in the refrigerant circuit 102 rises and the pressure difference generated by the compressor 111 becomes small, the power consumption can be reduced.

Embodiment 4.
Subsequently, the fourth embodiment will be described focusing on the differences from the first embodiment described above. For the same or equivalent configuration as that of the first embodiment, the same reference numerals are used, and the description thereof will be omitted or simplified. As shown in FIG. 9, the air conditioner 100 according to the present embodiment is different from the one according to the first embodiment in that the indoor unit 120 has an estimation unit 129b for estimating user attributes. ing.

The estimation unit 129b according to the present embodiment creates data representing the heat distribution in the indoor space from the infrared intensity distribution measured by the sensor 127a. Then, the estimation unit 129b estimates the user's attributes including the user's age, gender, sensible temperature, limb temperature, cold or hot characteristics, etc. based on the created heat distribution, and controls the estimation result 129. Send to. The control unit 129 determines whether or not the transition condition is satisfied according to the estimation result by the estimation unit 129b.

As described above, the transition conditions according to the present embodiment are satisfied according to the attributes of the user. Here, even if the user's feeling of warmth and coldness is within the neutral range, it may be felt cold due to the coldness of the toes. Therefore, when the coldness of the toes is estimated by the estimation unit 129b, the control unit 129 corrects the first threshold value for room temperature to a high value and the second threshold value for humidity to a low value among the transition conditions. If the operation mode is changed after this, both the warm and cold feeling of the whole body and the local warm and cold feeling of the toes or hands can be kept in a comfortable state.

Further, when a hot user and a cold user are in the same indoor space, the control unit 129 corrects the first temperature and the second humidity according to the cold user, and the hot user. You may direct the airflow to. Further, even when users of different genders and age bands are present in the same indoor space, the control unit 129 modifies the first threshold value, the second threshold value, etc. based on the user having a higher priority, and uses the reference. The airflow may be controlled according to an outside user. As a result, the comfort of a plurality of users as a whole can be improved.

The user's body temperature estimated by the estimation unit 129b may be used instead of the body temperature measured by the body temperature detection unit 140a according to the third embodiment. That is, in the third embodiment, the body temperature detection unit 140a built in the terminal 140 may be omitted to configure the air conditioner 100, and the user's body temperature may be detected by the estimation unit 129b according to the present embodiment.

Embodiment 5.
Subsequently, the fifth embodiment will be described focusing on the differences from the first embodiment described above. For the same or equivalent configuration as that of the first embodiment, the same reference numerals are used, and the description thereof will be omitted or simplified. The control unit 129 according to the present embodiment is different from that according to the first embodiment in that it controls the air volume of the indoor blower 124 when a specific condition is satisfied.

FIG. 10 shows the relationship between the sensible heat capacity and the latent heat capacity of the air conditioner 100 according to the present embodiment. When the control unit 129 reduces the air volume of the indoor blower 124, the latent heat capacity increases as shown by the white arrows in FIG.

Here, when the compressor 111 operates at a relatively small operating frequency in the first cooling mode and the second cooling mode, it is considered that the humidity in the indoor space tends to increase because the latent heat capacity is small. Therefore, when the condition that the temperature in the indoor space is below the threshold value and the humidity is higher than the threshold value is satisfied, the control unit 129 can increase the latent heat capacity by reducing the air volume of the indoor blower 124. This makes it possible to control a wide range of sensible heat capacity and latent heat capacity. That is, it is possible not only to realize one point of sensible heat capacity and latent heat capacity corresponding to one-to-one by control, but also to increase the latent heat capacity while maintaining the sensible heat capacity. As a result, fluctuations in temperature and humidity in the indoor space can be suppressed.

Although the embodiments of the present disclosure have been described above, the present disclosure is not limited to the above embodiments.

For example, the first expansion valve 115 and the second expansion valve 123 may have a function of finely eliminating air bubbles and droplet particles of the inflowing two-phase refrigerant to muffle the sound.

Further, the sensors 125a and 126a may be provided outside the indoor unit, for example, at the terminal 140.

Further, the function of the control unit 129 is divided into an outdoor control unit and an indoor control unit, the outdoor unit 110 has an outdoor control unit that controls each component of the outdoor unit 110, and the indoor unit 120 is an indoor unit. It may have an indoor control unit that controls each component of 120.

Further, even if the second expansion valve 123 is fully opened in the first cooling mode, the opening degree is not sufficient and the refrigerant may be depressurized. Therefore, a bypass circuit that bypasses the second expansion valve 123 may be added to the refrigerant circuit 102, and an electromagnetic valve connected in parallel with the second expansion valve 123 may be provided. When the solenoid valve is provided, the solenoid valve is fully opened in the first cooling mode. As a result, the pressure loss of the refrigerant can be prevented and the refrigerant circuit 102 can be operated efficiently.

Further, the program P1 stored in the EEPROM of the control unit 129 can be read by a computer such as a flexible disk, a CD-ROM (Compact Disk Read-Only Memory), a DVD (Digital Versatile Disk), or an MO (Magneto-Optical disk). A device that executes the above-described processing can be configured by storing and distributing the program P1 in a various recording medium and installing the program P1 on a computer.

Further, the program P1 may be stored in a disk device of a server device on a communication network represented by the Internet, superimposed on a carrier wave, and downloaded to a computer, for example.

The above process can also be achieved by starting and executing the program P1 while transferring it via a network represented by the Internet.

Further, the above-mentioned processing can also be achieved by executing all or a part of the program P1 on the server device and executing the program P1 while the computer sends and receives information about the processing via the communication network. ..

When the above-mentioned functions are shared by the OS (Operating System) or realized by collaboration between the OS and the application, only the parts other than the OS may be stored in the medium and distributed. , You may also download it to your computer.

Further, the means for realizing the function of the air conditioner 100 is not limited to software, and a part or all of the software may be realized by dedicated hardware. For example, if the acquisition unit 128, the control unit 129, and the estimation unit 129b are configured by using a circuit typified by an FPGA (Field Programmable Gate Array) or an ASIC (Application Specific Integrated Circuit), the power saving of the air conditioner 100 can be reduced. Can be planned.

The present disclosure allows for various embodiments and variations without departing from the broad spirit and scope of the present disclosure. Moreover, the above-described embodiment is for explaining the present disclosure, and does not limit the scope of the present disclosure. That is, the scope of the present disclosure is indicated by the scope of claims, not by the embodiment. And various modifications made within the scope of the claims and within the equivalent meaning of disclosure are considered to be within the scope of the present disclosure.

The present disclosure is suitable for techniques for harmonizing the air in an indoor space.

100 Air conditioner, 101 Refrigerant piping, 102 Refrigerant circuit, 110 Outdoor unit, 111 Compressor, 112 Four-way valve, 113 Outdoor heat exchanger, 114 Outdoor blower, 115 First expansion valve, 116a, 117a, 121a, 122a, 125a , 126a, 127a, 150a sensor, 120 indoor unit, 121 1st indoor heat exchanger, 122 2nd indoor heat exchanger, 123 2nd expansion valve, 124 indoor blower, 128 acquisition unit, 129 control unit, 129b estimation unit, 140 terminal, 140a body temperature detector, L1, L2, L11, L12 line, P1 program.

Claims (6)

An air conditioner that operates in an operation mode selected from the first cooling mode, the second cooling mode, and the dehumidification mode.
A refrigerant circuit that circulates refrigerant through a compressor, an outdoor heat exchanger, a first expansion valve, a first indoor heat exchanger, a second expansion valve, and a second indoor heat exchanger in this order.
Temperature information indicating the temperature of the air in the indoor space to be air conditioned, and an acquisition unit that acquires weather information,
An indoor air blowing means for blowing air exchanged by the first indoor heat exchanger and the second indoor heat exchanger into the indoor space is provided.
In the first cooling mode, the refrigerant evaporation temperature of the first chamber heat exchanger becomes equal to the refrigerant evaporation temperature of the second chamber heat exchanger.
In the second cooling mode, the refrigerant evaporation temperature of the first chamber heat exchanger is higher than the refrigerant evaporation temperature of the second chamber heat exchanger and lower than the temperature indicated by the temperature information.
In the dehumidification mode, the refrigerant evaporation temperature of the first chamber heat exchanger becomes higher than the temperature indicated by the temperature information.
When the predetermined conditions are satisfied according to the weather information, the operation mode shifts from one mode of the first cooling mode, the second cooling mode, and the dehumidification mode to the other mode.
The operation mode for shifting from the first cooling mode is the second cooling mode.
The operation mode for shifting from the second cooling mode is the first cooling mode or the dehumidifying mode.
The operation mode that shifts from the dehumidification mode is the air conditioner, which is the second cooling mode. An air conditioner that operates in an operation mode selected from the first cooling mode, the second cooling mode, and the dehumidification mode.
A refrigerant circuit that circulates refrigerant through a compressor, an outdoor heat exchanger, a first expansion valve, a first indoor heat exchanger, a second expansion valve, and a second indoor heat exchanger in this order.
Temperature information indicating the temperature of the air in the indoor space to be air conditioned, and an acquisition unit that acquires weather information,
An indoor blower means for blowing air exchanged by the first indoor heat exchanger and the second indoor heat exchanger into the indoor space.
An outdoor air blowing means for generating an air flow passing through the outdoor heat exchanger is provided.
In the first cooling mode, the refrigerant evaporation temperature of the first chamber heat exchanger becomes equal to the refrigerant evaporation temperature of the second chamber heat exchanger.
In the second cooling mode, the refrigerant evaporation temperature of the first chamber heat exchanger is higher than the refrigerant evaporation temperature of the second chamber heat exchanger and lower than the temperature indicated by the temperature information.
In the dehumidification mode, the refrigerant evaporation temperature of the first chamber heat exchanger becomes higher than the temperature indicated by the temperature information.
The dehumidifying mode includes a first dehumidifying mode and a second dehumidifying mode in which the air volume of the outdoor blowing means is smaller than the air volume in the first dehumidifying mode.
When the predetermined conditions are satisfied according to the weather information, the operation mode is selected from one of the first cooling mode, the second cooling mode, the first dehumidifying mode, and the second dehumidifying mode. Move to another mode and
The operation mode for shifting from the first cooling mode is the second cooling mode.
The operation mode for shifting from the second cooling mode is the first cooling mode or the first dehumidification mode.
The operation mode for shifting from the first dehumidification mode is the second cooling mode or the second dehumidification mode.
The operation mode for shifting from the second dehumidification mode is the air conditioner, which is the first dehumidification mode. It is an air conditioning method that blows conditioned air into the indoor space in the operation mode selected from the first cooling mode, the second cooling mode, and the dehumidification mode.
In the first cooling mode, the refrigerant circuit that circulates the refrigerant through the compressor, the outdoor heat exchanger, the first expansion valve, the first indoor heat exchanger, the second expansion valve, and the second indoor heat exchanger in this order. The refrigerant evaporation temperature of the first chamber heat exchanger becomes equal to the refrigerant evaporation temperature of the second chamber heat exchanger.
In the second cooling mode, the refrigerant evaporation temperature of the first chamber heat exchanger is higher than the refrigerant evaporation temperature of the second chamber heat exchanger and lower than the temperature of air in the chamber space.
In the dehumidification mode, the refrigerant evaporation temperature of the first indoor heat exchanger becomes higher than the temperature of the air in the indoor space.
When the predetermined conditions are satisfied according to the weather information, the operation mode shifts from one mode of the first cooling mode, the second cooling mode, and the dehumidification mode to the other mode.
The operation mode for shifting from the first cooling mode is the second cooling mode.
The operation mode for shifting from the second cooling mode is the first cooling mode or the dehumidifying mode.
The operation mode for shifting from the dehumidification mode is the air conditioning method, which is the second cooling mode. It is an air conditioning method that blows conditioned air into the indoor space in the operation mode selected from the first cooling mode, the second cooling mode, and the dehumidification mode.
In the first cooling mode, the refrigerant circuit that circulates the refrigerant through the compressor, the outdoor heat exchanger, the first expansion valve, the first indoor heat exchanger, the second expansion valve, and the second indoor heat exchanger in this order. The refrigerant evaporation temperature of the first chamber heat exchanger becomes equal to the refrigerant evaporation temperature of the second chamber heat exchanger.
In the second cooling mode, the refrigerant evaporation temperature of the first chamber heat exchanger is higher than the refrigerant evaporation temperature of the second chamber heat exchanger and lower than the temperature of air in the chamber space.
In the dehumidification mode, the refrigerant evaporation temperature of the first indoor heat exchanger becomes higher than the temperature of the air in the indoor space.
The dehumidification mode includes a first dehumidification mode and a second dehumidification mode in which the air volume of the outdoor air blowing means for generating an air flow passing through the outdoor heat exchanger is smaller than the air volume in the first dehumidification mode.
Operation mode, the predetermined condition is satisfied in accordance with weather information, other from one mode of the first cooling mode and the second cooling mode and the first dehumidification mode and the second dehumidification mode Move to the mode of
The operation mode for shifting from the first cooling mode is the second cooling mode.
The operation mode for shifting from the second cooling mode is the first cooling mode or the first dehumidification mode.
The operation mode for shifting from the first dehumidification mode is the second cooling mode or the second dehumidification mode.
The operation mode for shifting from the second dehumidification mode is the air conditioning method, which is the first dehumidification mode. A computer that controls an air conditioner,
Temperature information indicating the temperature of the air in the indoor space to be air conditioned, and acquisition means for acquiring weather information,
A control means that controls the operation mode of the air conditioner and selects one operation mode from the first cooling mode, the second cooling mode, and the dehumidification mode.
To function as
In the first cooling mode, the compressor, the outdoor heat exchanger, the first expansion valve, the first indoor heat exchanger, the second expansion valve, and the second indoor heat exchanger constituting the air conditioner are passed in this order. In the refrigerant circuit that circulates the refrigerant, the refrigerant evaporation temperature of the first chamber heat exchanger becomes equal to the refrigerant evaporation temperature of the second chamber heat exchanger.
In the second cooling mode, the refrigerant evaporation temperature of the first chamber heat exchanger is higher than the refrigerant evaporation temperature of the second chamber heat exchanger and lower than the temperature indicated by the temperature information.
In the dehumidification mode, the refrigerant evaporation temperature of the first chamber heat exchanger becomes higher than the temperature indicated by the temperature information.
When the predetermined conditions are satisfied according to the weather information, the operation mode shifts from one mode of the first cooling mode, the second cooling mode, and the dehumidification mode to the other mode.
The operation mode for shifting from the first cooling mode is the second cooling mode.
The operation mode for shifting from the second cooling mode is the first cooling mode or the dehumidifying mode.
The operation mode for shifting from the dehumidification mode is the second cooling mode, which is a program. A computer that controls an air conditioner,
Temperature information indicating the temperature of the air in the indoor space to be air conditioned, and acquisition means for acquiring weather information,
A control means that controls the operation mode of the air conditioner and selects one operation mode from the first cooling mode, the second cooling mode, and the dehumidification mode.
To function as
In the first cooling mode, the compressor, the outdoor heat exchanger, the first expansion valve, the first indoor heat exchanger, the second expansion valve, and the second indoor heat exchanger constituting the air conditioner are passed in this order. In the refrigerant circuit that circulates the refrigerant, the refrigerant evaporation temperature of the first chamber heat exchanger becomes equal to the refrigerant evaporation temperature of the second chamber heat exchanger.
In the second cooling mode, the refrigerant evaporation temperature of the first chamber heat exchanger is higher than the refrigerant evaporation temperature of the second chamber heat exchanger and lower than the temperature indicated by the temperature information.
In the dehumidification mode, the refrigerant evaporation temperature of the first chamber heat exchanger becomes higher than the temperature indicated by the temperature information.
The dehumidification mode includes a mode humidity first removal, and the second dehumidification mode smaller than the air volume air volume is in the first dehumidification mode of the outdoor blower means for generating a pre-Symbol air flow passing through the outdoor heat exchanger, a,
When the predetermined conditions are satisfied according to the weather information, the operation mode is selected from one of the first cooling mode, the second cooling mode, the first dehumidifying mode, and the second dehumidifying mode. Move to another mode and
The operation mode for shifting from the first cooling mode is the second cooling mode.
The operation mode for shifting from the second cooling mode is the first cooling mode or the first dehumidification mode.
The operation mode for shifting from the first dehumidification mode is the second cooling mode or the second dehumidification mode.
The operation mode for shifting from the second dehumidification mode is the first dehumidification mode, the program.

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