JP2022118949A - air conditioning system - Google Patents

Abstract

To provide an air conditioning system capable of suppressing unevenness of temperature distribution in a room.SOLUTION: An air conditioning system comprises a ventilation device, a circulation device, and a control device that controls the operation of the circulation device. When the control device determines that temperature distribution is disturbed by the operation of the ventilation device or the opening of a room, the control device causes the circulation device to perform circulation operation.SELECTED DRAWING: Figure 4

Description

The present disclosure relates to air conditioning systems.

Air conditioners with ventilators are known. For example, in the technique described in Patent Literature 1, air supplied from the outside is emitted from the vicinity of the air outlet of the indoor unit.

JP 2012-220133 A

Ventilation may be performed by operating the ventilation device in an air conditioner having a ventilation device, or by operating a ventilation device provided separately from the air conditioner in the room. In any case, when ventilation is performed, uneven temperature distribution occurs in the room, which may impair the comfort of the room.

An air conditioning system that solves this problem is an air conditioning system that includes a ventilation device, a circulation device, and a control device that controls the operation of the circulation device, wherein the control device controls the operation of the ventilation device or the interior of the room. When it is determined that the temperature distribution is disturbed by the opening, the circulation device is caused to perform the circulation operation. According to this configuration, the circulation operation is performed based on the fact that it is determined that the temperature distribution is disturbed. Thereby, uneven temperature distribution in the room can be suppressed.

In the above air conditioning system, when the outdoor temperature is lower than the indoor temperature, the indoor temperature change per unit time is negative, and when the temperature change is lower than a first predetermined value, Alternatively, when the outdoor temperature is higher than the indoor temperature and the temperature change is positive and the temperature change is higher than the second predetermined value, it is determined that the temperature distribution is disturbed. According to this configuration, it is possible to determine whether or not the temperature distribution is disturbed based on the temperature change in the room. In this way, it is possible to determine whether or not the temperature distribution is disturbed with a simple configuration.

In the above air conditioning system, the controller causes a disturbance in the temperature distribution when the temperature difference between the indoor temperature and the outdoor temperature is greater than a third predetermined value and ventilation is being performed by the ventilation device. Judge the situation.

According to this configuration, it is possible to determine whether or not the temperature distribution will be disturbed based on the temperature difference between the indoor temperature and the outdoor temperature and the execution of ventilation. This makes it possible to accurately determine whether or not the temperature distribution is disturbed.

In the air conditioning system described above, the controller controls that, when the outdoor temperature is lower than the indoor temperature, the refrigerant temperature change per unit time is negative, and the refrigerant temperature change is lower than a fourth predetermined value. or when the outdoor temperature is higher than the indoor temperature, the coolant temperature change is positive, and the coolant temperature change is higher than a fifth predetermined value, the temperature distribution is disturbed. I judge. According to this configuration, it is possible to determine whether or not the temperature distribution is disturbed based on the change in the coolant temperature. In this way, it is possible to determine whether or not the temperature distribution is disturbed with a simple configuration.

In the above air conditioning system, the control device receives a signal indicating the operating state of the ventilation device from the ventilation device and determines that the temperature distribution is disturbed.
According to this configuration, it is determined whether or not the temperature distribution will be disturbed based on the information as to whether or not the ventilator is in operation. In this way, it is possible to determine whether or not the temperature distribution is disturbed with a simple configuration.

The above air conditioning system further comprises an operation device that receives an input to operate the ventilation device and transmits a command based on the input to the ventilation device and the control device, wherein the control device receives the command from the operation device. It is determined that the reception causes a disturbance in the temperature distribution. According to this configuration, it is determined whether or not the temperature distribution will be disturbed based on the input for operating the ventilation device in the operation device. In this way, it is possible to determine whether or not the temperature distribution is disturbed with a simple configuration.

In the above air conditioning system, when the temperature difference between the indoor temperature and the outdoor temperature is smaller than a sixth predetermined value, regardless of whether or not it is determined that the temperature distribution is disturbed, The circulation device is not allowed to perform the circulation operation.

According to this configuration, the circulation operation is not performed when the temperature difference between the indoor temperature and the outdoor temperature is smaller than the sixth predetermined value in a situation where it is determined that the temperature distribution is disturbed. As a result, useless circulation operation, which is performed when unevenness in temperature distribution is unlikely to occur, can be suppressed.

In the above air conditioning system, the circulation device has a wind direction adjustment unit having a louver for adjusting the direction of wind, and the control device controls, when the circulation operation is performed, the outdoor temperature is higher than the indoor temperature, and the When the temperature difference between the outdoor temperature and the indoor temperature is equal to or greater than a seventh predetermined value, the angle of the louver is adjusted to an angle larger than the first angle with reference to the lower limit angle, and the outdoor temperature is higher than the indoor temperature. When the temperature difference between the outdoor temperature and the indoor temperature is equal to or greater than an eighth predetermined value, the angle of the louver is adjusted to be smaller than the second angle with respect to the lower limit angle.

When the outdoor temperature is higher than the indoor temperature, air tends to accumulate in the upper layers of the room. In the above configuration, in such a case, since the air is discharged upward, the air accumulated in the upper layer of the room can be quickly circulated. Also, when the outdoor temperature is lower than the indoor temperature, air tends to accumulate in the lower layers of the room. In the above configuration, in such a case, since the air is discharged downward, the air accumulated in the lower layer of the room can be quickly circulated.

The above air conditioning system further comprises an airflow direction control device that receives an input for setting the angle of the louver and transmits a command based on the input to the circulation device and the control device, wherein the control device receives the command and the louver angle is set between the louver angle set in the command and the louver angle set in the circulation operation. set to an angle.

According to this configuration, when the angle of the louver is set based on the information input to the wind direction control device and it is determined that the temperature distribution is disturbed, the angle of the louver is set to the set angle. Effective circulation can be achieved without changing the angle significantly.

The schematic diagram of the air-conditioning system of 1st Embodiment. Schematic diagram of a wind direction adjusting unit. Flowchart of control of circulation operation. 4 is a flowchart of a process for determining whether or not a disturbance in temperature distribution occurs. 5 is a chart showing the relationship between changes in room temperature, changes in room temperature, and circulation operation. The schematic diagram of the air-conditioning system of 2nd Embodiment.

<First embodiment>
The air conditioning system of the first embodiment will be described with reference to FIGS. 1 to 5. FIG.
The air conditioning system 1 includes a circulation device 2 , a control device 3 that controls the operation of the circulation device 2 , and a ventilation device 4 . Furthermore, the air conditioning system 1 may comprise a detection device 5 for detecting the ventilation operation of the ventilation device 4 .

The circulation device 2 circulates the air in the room or disturbs the air in the room. The circulation device 2 has a blower section 6 . The blower 6 draws in indoor air and blows out the sucked air from an outlet of the blower 6 . The circulation device 2 circulates the air in the room or disturbs the air in the room by blowing air formed by the air blowing section 6 .

The circulation device 2 preferably has a wind direction adjusting section 7 . The wind direction adjusting unit 7 has a louver 7A for adjusting the wind direction. The circulation device 2 changes the direction of the blown air by changing the angle of the louver 7A.

The circulation device 2 may comprise an operating device 8 . The operation device 8 is a device for specifying the priority of execution of the circulation operation. Furthermore, the circulation device 2 may comprise a wind direction manipulating device 9 . The wind direction control device 9 receives an input for setting the angle of the louver 7A and transmits a command based on the input to the circulation device 2 and the control device 3 .

Examples of the circulation device 2 include an air conditioner 10, an electric fan, an air cleaner, a humidifier, and a fan heater. The air conditioning system 1 of this embodiment has an air conditioner 10 as a circulation device 2 .

The air conditioner 10 includes an indoor heat exchanger 11 , an outdoor heat exchanger 12 , a compressor 13 and a control device 3 . Furthermore, the air conditioner 10 includes an expansion valve 14 and a switching valve 15 . Air conditioner 10 includes a refrigerant circuit 20 . The refrigerant circuit 20 includes an indoor heat exchanger 11, an outdoor heat exchanger 12, a compressor 13, an expansion valve 14, a switching valve 15, and a refrigerant pipe 16 connecting these. Compressor 13 compresses the refrigerant. The expansion valve 14 expands the refrigerant. Furthermore, the air conditioner 10 may include an operating device 8 . Furthermore, the air conditioner 10 includes a wind direction control device 9 . Furthermore, the air conditioner 10 may include a notification device 19 .

In one example, the air conditioner 10 includes an indoor unit 21 placed indoors and an outdoor unit 22 placed outdoors.
The indoor unit 21 has an indoor heat exchanger 11 . Furthermore, the indoor unit 21 has a blower section 6 . The blower section 6 includes a fan 6A and a fan motor 6B. Furthermore, the indoor unit 21 has a wind direction adjusting section 7 . The outdoor unit 22 includes an outdoor heat exchanger 12 , a compressor 13 , an expansion valve 14 and a switching valve 15 .

Compressor 13 includes a motor and an inverter. The inverter changes the frequency of electric power supplied to the motor (hereinafter referred to as "operating frequency" or "operating frequency of compressor 13") to operate the motor. The rotation speed of the compressor 13 changes according to changes in the operating frequency. The inverter changes the operating frequency based on commands from the control device 3 .

The switching valve 15 switches the direction of flow of the refrigerant. An example of the switching valve 15 is a four-way switching valve. Specifically, in the cooling operation, the switching valve 15 is connected to the refrigerant pipe 16 extending from the outdoor heat exchanger 12 so that the refrigerant flows from the compressor 13 to the outdoor heat exchanger 12 based on a command from the control device 3. A discharge port of the compressor 13 is connected. In the heating operation, the switching valve 15 connects the refrigerant pipe 16 extending from the indoor heat exchanger 11 and the discharge port of the compressor 13 so that the refrigerant flows from the compressor 13 to the indoor heat exchanger 11 based on a command from the control device 3 . Connect with the exit.

The air blower 6 is provided downstream of the indoor heat exchanger 11 in the air circulation path from the inlet of the indoor unit 21 to the outlet. Examples of the fan 6A of the blower section 6 are a sirocco fan and a cross flow fan.

As shown in FIG. 2, the wind direction adjusting unit 7 includes a louver 7A and a motor 7B that rotates the louver 7A. The louver 7A is provided downstream of the air blower 6 in the air circulation path from the inlet of the indoor unit 21 to the outlet. The louver 7A changes the wind direction by changing the angle of the louver 7A. The wind direction adjusting unit 7 changes the angle of the louver 7A according to a command issued from the control device 3. FIG.

The operation device 8 remotely operates the air conditioner 10 . The operating device 8 may include a wind direction operating device 9 . The operating device 8 has an input section 8A and an output section 8B. The input unit 8A accepts user input. Examples of inputs include an input for cooling the air conditioner 10, an input for heating the air conditioner 10, an input for setting the angle of the louver 7A, and the priority and execution of the circulation operation. input for specifying the prohibition of The output unit 8B outputs a command based on the input received by the input unit 8A as a radio signal. Examples of wireless signals are optical signals and radio signals.

The execution priority of the circulation operation includes two items of "priority" and "secondary priority". “Priority” indicates that the specified angle of the louver 7A based on the circulation operation is given priority over the specified angle of the louver 7A based on the input in the operation device 8. FIG. "Secondary priority" indicates that the specified angle of the louver 7A is changed to an angle between the specified angle of the louver 7A based on the input in the operation device 8 and the specified angle of the louver 7A based on the circulation operation. "Prohibition" of the execution of the circulation operation indicates that the circulation operation is not performed even when the conditions for performing the circulation operation are satisfied. The operation device 8 accepts three settings of "priority", "semi-priority", and "prohibition" for the execution of the circulation operation.

An example of the operating device 8 is a remote control. The operating device 8 may be a mobile terminal. An example of a mobile terminal is a smart phone. An application for operating the air conditioner 10 is installed in the smartphone.

The notification device 19 includes at least one of a sound output section 19A and a display section 19B. The notification device 19 notifies the user of operation-related information regarding the operation of the air conditioner 10 . The operation-related information includes information indicating that the circulation operation, which will be described later, has started, and information indicating that the circulation operation has ended. The notification device 19 may be provided in the indoor unit 21 or may be provided in the operation device 8 .

19 A of sound output parts output driving|operation related information as a sound based on the instruction|command of the control apparatus 3. FIG. 19 A of sound output parts are equipped with a speaker. The sound output from the sound output unit 19A may be a sound indicating the start or end of the circulation operation, or may be a predetermined sound or melody.

The display unit 19</b>B outputs driving-related information as visual information based on commands from the control device 3 . The display unit 19B has a monitor. The information displayed by the display unit 19B may be characters representing the start or end of the circulation operation, or may be predetermined pictorial symbols.

The ventilation device 4 is configured as a separate device from the air conditioner 10 . The ventilator 4 includes at least one of indoor air exhaust and outdoor air supply. The ventilation device 4 has a fan. Examples of the ventilation device 4 include a ventilation fan, a total heat exchanger, and a duct with a blower.

A detection device 5 detects whether or not the ventilator 4 is in operation. In one example, the detection device 5 is provided in a commercial power source that supplies power to the ventilation device 4 and detects power supplied to the ventilation device 4 from the commercial power source. An example of such a detection device 5 is a watt checker. When the detection device 5 detects the power required to rotate the fan of the ventilation device 4, the detection device 5 sends a signal to the control device 3 of the air conditioner 10 indicating that the ventilation device 4 is performing ventilation (hereinafter referred to as " Ventilation detection signal”) is output.

Control device 3 controls compressor 13 and expansion valve 14 . The control device 3 receives commands issued from the operation device 8 and performs various controls according to the commands. Examples of control by the control device 3 include cooling operation, heating operation, and wind direction control. Further, when the control device 3 determines that the temperature distribution is disturbed by the operation of the ventilation device 4, the control device 3 causes the circulation device 2 to perform the circulation operation.

The control device 3 has a CPU (Central Processing Unit) or MPU (Micro-processor Unit) and a memory. The control device 3 performs various controls based on programs and various information stored in the memory. Various types of information include commands issued from the operating device 8 and detection values issued from various sensors provided in the air conditioner 10 . Various sensors include an indoor temperature sensor 25, an outdoor temperature sensor 26, and a refrigerant temperature sensor 27.

The indoor temperature sensor 25 outputs information corresponding to the indoor temperature TA to the control device 3 . In one example, the indoor temperature sensor 25 is provided in the indoor unit 21 . The outdoor temperature sensor 26 outputs information corresponding to the outdoor temperature TB to the control device 3 . In one example, the outdoor temperature sensor 26 is provided on the outdoor unit 22 . The refrigerant temperature sensor 27 outputs information corresponding to the refrigerant temperature in the downstream portion of the indoor heat exchanger 11 or in the vicinity of the refrigerant outlet to the control device 3 . In one example, the refrigerant temperature sensor 27 is provided in the indoor unit 21 .

The control device 3 is provided in the outdoor unit 22 . The control device 3 may be provided in the indoor unit 21 . The control device 3 may be configured by a plurality of units, and the plurality of units may be provided in each of the indoor unit 21 and the outdoor unit 22 . A part of the program used by the control device 3 may be stored in a server on the network. In this case, the control device 3 communicates with a server on the network as necessary to use the program.

The control device 3 has compressor operation control as control of the compressor 13 . The control device 3 executes compressor operation control when performing cooling operation or heating operation. In the present embodiment, cooling operation or heating operation is also referred to as "air conditioning operation".

Compressor operation control is control for operating the compressor 13 within a predetermined operating frequency range. In compressor operation control, the controller 3 changes the operating frequency of the compressor 13 based on the set temperature TX and the room temperature TA. In one example, the control device 3 changes the operating frequency of the compressor 13 based on the temperature difference between the set temperature TX and the indoor temperature TA. The controller 3 lowers the operating frequency of the compressor 13 when the temperature difference between the set temperature TX and the room temperature TA becomes smaller. The controller 3 increases the operating frequency of the compressor 13 when the temperature difference between the set temperature TX and the room temperature TA increases.

The control device 3 executes circulation operation by circulation control. The control device 3 changes the angle of the louver 7A as circulation control. The control device 3 rotates the fan 6A of the air blower 6 in addition to changing the angle of the louver 7A when the air conditioning operation is not being performed. The control device 3 changes only the angle of the louver 7A and controls the rotational speed of the fan 6A of the air blower 6 based on the control of the air conditioning operation when the air conditioning operation is being performed.

The control device 3 executes the circulation operation based on the input to the operation device 8 regarding the circulation operation. Inputs are "prohibition", "priority", and "secondary priority" of the circulation operation. Furthermore, for the purpose of determining whether or not to execute the circulation operation, the control device 3 determines whether or not the temperature distribution is disturbed based on the operation of the ventilator 4 .

The control device 3 stops the circulation operation after a predetermined time has elapsed since the start of the circulation operation. The control device 3 may stop the circulation operation when a predetermined condition is satisfied. An example of the predetermined condition is a condition that the temperature difference between the room temperature TA of the upper layer of the room and the room temperature TA of the lower layer of the room is smaller than a set value.

An example of a method for determining a situation in which the temperature distribution is disturbed will be described.
The control device 3 acquires the indoor temperature TA and the outdoor temperature TB. The controller 3 calculates an indoor temperature change DT based on the indoor temperature TA. The indoor temperature change DT indicates the temperature change per unit time. For example, if the room temperature TA at time t1 is T1 and the room temperature TA at time t2 is T2, the temperature change DT is defined by (T2-T1)/(t2-t1).

When the outdoor temperature TB is lower than the indoor temperature TA, the indoor temperature change DT is negative, and when the temperature change DT is lower than the first predetermined value A1, the controller 3 controls the disturbance of the temperature distribution. Determine the situation that arises. The first predetermined value A1 is a negative value. The first predetermined value A1 is a value lower than the lower limit of the temperature change DT that can normally occur in an unventilated room.

When the outdoor temperature TB is higher than the indoor temperature TA, the temperature change DT is positive, and the temperature change DT is higher than the second predetermined value, the controller 3 assumes that the temperature distribution is disturbed. judge. The second predetermined value is a positive value. The second predetermined value is a value higher than the upper limit of temperature change DT that can normally occur in an unventilated room.

Another example of a method for determining a situation in which the temperature distribution is disturbed will be described.
When the temperature difference between the indoor temperature TA and the outdoor temperature TB is greater than the third predetermined value and ventilation is being performed by the ventilation device 4, the control device 3 determines that the temperature distribution is disturbed. do.

Specifically, the control device 3 calculates the temperature difference between the indoor temperature TA and the outdoor temperature TB. The temperature difference is an absolute value. The control device 3 determines whether or not the temperature difference between the indoor temperature TA and the outdoor temperature TB is greater than a third predetermined value. Furthermore, the control device 3 determines whether or not ventilation is being performed by the ventilation device 4 based on the ventilation detection signal output from the detection device 5 .

Another example of a method for determining a situation in which the temperature distribution is disturbed will be described.
The control device 3 acquires the refrigerant temperature, the outdoor temperature TB, and the indoor temperature TA. The control device 3 calculates the coolant temperature change based on the coolant temperature. The refrigerant temperature change indicates the change in refrigerant temperature per unit time. For example, if the coolant temperature at time t1 is RT1 and the coolant temperature at time t2 is RT2, the coolant temperature change DRT is defined by (RT2-RT1)/(t2-t1).

When the outdoor temperature TB is lower than the indoor temperature TA, the coolant temperature change is negative, and the coolant temperature change is lower than the fourth predetermined value, the temperature distribution is disturbed. Judge the situation. The fourth predetermined value is a negative value. The fourth predetermined value is a value lower than the lower limit of refrigerant temperature change that can normally occur in an unventilated room.

When the outdoor temperature TB is higher than the indoor temperature TA, the coolant temperature change is positive, and the coolant temperature change is higher than the fifth predetermined value, the control device 3 determines that the temperature distribution is disturbed. I judge. The fifth predetermined value is a positive value. The fifth predetermined value is a value higher than the upper limit of refrigerant temperature change that can normally occur in an unventilated room.

When executing the circulation operation, the control device 3 adjusts the angle of the louver 7A like the following first adjustment and second adjustment.
The "first adjustment" will be explained. When the outdoor temperature TB is higher than the indoor temperature TA and the temperature difference between the outdoor temperature TB and the indoor temperature TA is equal to or greater than the seventh predetermined value, the controller 3 sets the angle of the louver 7A to the lower limit angle R0. , to an angle greater than the first angle R1 (see FIG. 2). The temperature difference is an absolute value. The seventh predetermined value is a positive value.

A specific example of adjusting the angle of the louver 7A will be described with reference to FIG.
The control device 3 adjusts the louver 7A within the range from the cooling lower limit position P1 to the cooling upper limit position P2 during normal cooling operation. The angle of the cooling upper limit position P2 is the first angle R1 with respect to the lower limit angle R0 of the louver 7A. The angle of the cooling lower limit position P1 is a second angle R2 with the lower limit angle R0 of the louver 7A as a reference.

The control device 3 adjusts the louver 7A to a position above the cooling upper limit position P2 when the conditions for the circulation operation are satisfied during the cooling operation. The angle of the louver 7A at a position above the cooling upper limit position P2 is larger than the first angle R1 with respect to the lower limit angle R0 of the louver 7A.

When the outdoor temperature TB is higher than the indoor temperature TA, such as in summer, when the outdoor air enters the room, the outdoor air accumulates in the upper layers of the room. For the purpose of circulating or disturbing the air accumulated in the upper layers of the room, the control device 3 causes the air blower 6 to direct the air blowing upward under the control of the wind direction adjusting unit 7 .

"Second adjustment" will be explained. When the outdoor temperature TB is lower than the indoor temperature TA and the temperature difference between the outdoor temperature TB and the indoor temperature TA is equal to or greater than the eighth predetermined value, the controller 3 sets the angle of the louver 7A to the lower limit angle R0. , to an angle smaller than the second angle R2 (see FIG. 2). The temperature difference is an absolute value. The eighth predetermined value is a positive value.

A specific example of adjusting the angle of the louver 7A will be described with reference to FIG.
The control device 3 adjusts the louver 7A within a range from the lower heating limit position P3 to the upper heating upper limit position P4 during normal heating operation. The angle of the heating upper limit position P4 is the first angle R1 with respect to the lower limit angle R0 of the louver 7A. The angle of the heating lower limit position P3 is a second angle R2 with the lower limit angle R0 of the louver 7A as a reference. In FIG. 2, the heating upper limit position P4 is at the same position as the cooling upper limit position P2, but it may be at a different position from the cooling upper limit position P2. The heating lower limit position P3 is the same as the cooling lower limit position P1, but may be different from the cooling lower limit position P1.

The control device 3 adjusts the louver 7A to a position below the heating lower limit position P3 when the conditions for the circulation operation are satisfied during the heating operation. The angle of the louver 7A at a position below the heating lower limit position P3 is smaller than the second angle R2 with respect to the lower limit angle R0 of the louver 7A.

When the outdoor temperature TB is lower than the indoor temperature TA as in winter, when the outdoor air enters the room, the outdoor air accumulates in the lower layer of the room. For the purpose of circulating or disturbing the air accumulated in the lower layers of the room, the control device 3 directs the air blowing from the air blowing section 6 downward under the control of the air direction adjusting section 7 .

When the control device 3 receives a command regarding the angle of the louver 7A from the wind direction control device 9 and determines that the temperature distribution is disturbed, the control device 3 adjusts the louver 7A according to the priority of the circulation operation. set the angle of The control device 3 has control for executing the circulation operation in the first mode and control for executing the circulation operation in the second mode according to the priority of the circulation operation.

When "prohibition" of the circulation operation is selected, the control device 3 does not perform the circulation operation regardless of whether or not it is determined that the temperature distribution will be disturbed.

When the "priority" of the circulation operation is selected, the control device 3 executes the circulation operation in the first mode. In the first aspect of the circulation operation, when the angle of the louver 7A is set to a predetermined angle in response to a command from the wind direction control device 9, the control device 3 resets the angle to circulate the angle of the louver 7A. Set the angle based on the ration operation.

The control device 3 executes the circulation operation in the second mode when the "secondary priority" of the circulation operation is selected. In the second mode of circulation operation, the control device 3 determines that the angle of the louver 7A is set to a predetermined angle in response to a command from the wind direction control device 9 and that the temperature distribution is disturbed. , the angle of the louver 7A is changed as follows. The control device 3 sets the angle of the louver 7A to an angle between the angle of the louver 7A set based on the command from the wind direction control device 9 and the angle of the louver 7A set in the circulation operation.

For example, when the control device 3 sets the angle of the louver 7A in response to a command from the wind direction control device 9, and determines that the temperature distribution is disturbed, the control device 3 changes the angle of the louver 7A to the angle of the louver 7A. It is set to an intermediate angle between the specified angle and the angle of the louver 7A set in the circulation operation.

When starting the circulation operation and when ending the circulation operation, the control device 3 outputs information corresponding to the start or end to the notification device 19 . Upon receiving information from the control device 3, the notification device 19 notifies the information.

When the notification device 19 includes the sound output unit 19A, the control device 3 issues a command to the notification device 19 to output a predetermined sound indicating the start when the circulation operation is started. Further, the control device 3 issues a command to the notification device 19 to output a predetermined sound indicating the end of the circulation operation when the circulation operation ends.

When the notification device 19 includes the display unit 19B, the control device 3 issues a command to the notification device 19 to display predetermined characters or pictorial symbols indicating execution of the circulation operation when the circulation operation is started. Further, the control device 3 issues a command to the notification device 19 to hide predetermined characters or pictorial symbols at the end of the circulation operation.

The control of the circulation operation executed by the control device 3 will be described with reference to FIG. 3 . Control of the circulation operation is control for selecting the operation mode of the circulation operation from the first mode and the second mode. In one example, the control device 3 periodically executes the flow of circulation operation control.

In step S<b>11 , the control device 3 executes a temperature distribution disturbance determination process to determine whether or not the temperature distribution is being disturbed.
When the control device 3 determines in step S11 that the temperature distribution is not disturbed, the flow is once terminated. After the end of the flow, the control device 3 restarts the flow after a predetermined period of time has elapsed. Note that hereinafter, the control device 3 simply ends the flow on the premise that the flow will be restarted after a predetermined period of time has elapsed, simply as “temporarily ending”.

When determining in step S11 that the temperature distribution is disturbed, the control device 3 determines in step S12 whether or not circulation is being performed. When the control device 3 determines in step S12 that the circulation is in progress, the flow is once terminated. After the end of the flow, the control device 3 restarts the flow after a predetermined period of time has elapsed. When the control device 3 determines in step S12 that the circulation is not being performed, in step S13, it determines whether or not the air conditioning operation is being performed.

When the control device 3 determines in step S13 that the air conditioning operation is not being performed, in step S15, the circulation operation is started in the first mode. When the controller 3 determines in step S13 that the air-conditioning operation is being performed, in step S14, it determines whether or not the circulation operation is "prioritized".

When the control device 3 determines in step S14 that the circulation operation is "priority", in step S15, it starts the circulation operation in the first mode. When the control device 3 determines in step S14 that the circulation operation is not "prioritized", in step S16, it starts the circulation operation in the second mode.

With reference to FIG. 4, an example of "determining whether or not the temperature distribution is disturbed" executed by the control device 3 will be described. The outdoor temperature TB and the indoor temperature TA are used in the "process for determining whether or not the temperature distribution is disturbed". The determination method of "determining whether or not the temperature distribution is disturbed" can also be applied when the coolant temperature is used.

In step S21, the controller 3 calculates the absolute value of the temperature difference between the outdoor temperature TB and the indoor temperature TA, and determines whether the temperature difference is smaller than the set value. When the control device 3 determines in step S21 that the temperature difference is smaller than the set value, the flow ends. When the control device 3 determines in step S21 that the temperature difference is equal to or greater than the set value, the process proceeds to step S22.

In step S22, the controller 3 determines whether the outdoor temperature TB is lower than the indoor temperature TA. When the controller 3 determines in step S22 that the outdoor temperature TB is equal to or higher than the indoor temperature TA, the process proceeds to step S26. When the controller 3 determines in step S22 that the outdoor temperature TB is lower than the indoor temperature TA, the process proceeds to step S23.

In step S23, the control device 3 determines whether or not the temperature change DT is negative. When the control device 3 determines that the temperature change DT is not negative in step S23, the flow ends. When determining that the temperature change DT is negative in step S23, the control device 3 proceeds to step S24.

In step S24, the control device 3 determines whether or not the temperature change DT is lower than the first predetermined value A1. When the control device 3 determines in step S24 that the temperature change DT is greater than or equal to the first predetermined value A1, the flow ends. When the control device 3 determines in step S24 that the temperature change DT is lower than the first predetermined value A1, the process proceeds to step S25.

In step S25, the controller 3 determines that "the temperature distribution is disturbed" and stores this as the determination result. This situation is a situation in which the temperature distribution is being disturbed due to a sudden drop in the room temperature TA.

The control device 3 performs the following processes after step S26.
In step S26, the controller 3 determines whether the outdoor temperature TB is higher than the indoor temperature TA. When the controller 3 determines in step S26 that the outdoor temperature TB is equal to or lower than the indoor temperature TA, the flow ends. When the controller 3 determines in step S26 that the outdoor temperature TB is higher than the indoor temperature TA, the process proceeds to step S27.

In step S27, the control device 3 determines whether or not the temperature change DT is positive. When the control device 3 determines that the temperature change DT is not positive in step S27, the flow ends. When the control device 3 determines that the temperature change DT is positive in step S27, the process proceeds to step S28.

In step S28, the control device 3 determines whether or not the temperature change DT is higher than the second predetermined value. When the control device 3 determines in step S28 that the temperature change DT is equal to or less than the second predetermined value, the flow ends. When the control device 3 determines in step S28 that the temperature change DT is higher than the second predetermined value, the process proceeds to step S25.

In step S25, the controller 3 determines that "the temperature distribution is disturbed" and stores this as the determination result. This situation is a situation in which the temperature distribution is being disturbed due to a sudden rise in the indoor temperature TA.

Referring to FIG. 5, the relationship between transition of room temperature TA, transition of temperature change DT, and circulation operation will be described. In this example, the outdoor temperature TB is lower than the indoor temperature TA. The air conditioner 10 is performing heating operation.

Before time t1, the indoor temperature TA is stable and changes little. The indoor temperature TA is maintained at a temperature close to the set temperature TX. At time t1, the room is ventilated. After time t1, the indoor temperature TA decreases, the temperature change DT is a negative value, and the temperature change DT also gradually increases to the negative side. At time t2, temperature change DT becomes smaller than first predetermined value A1. At this time, the control device 3 determines that "the temperature distribution is disturbed". Further, based on this determination, the control device 3 executes circulation operation. At time t3 after a predetermined time has passed since the start of the circulation operation, the circulation operation ends.

The operation of this embodiment will be described.
For human health, indoor ventilation is recommended. Insects such as ticks and mold easily propagate when the room is not well ventilated and damp, which affects human health. In addition, when there is a person infected with the virus, the virus tends to remain in the room, increasing the risk of infection to other people. However, when there is a large temperature difference between indoors and outdoors, such as in winter or summer, ventilation causes a disturbance in the temperature distribution inside the room. For example, a temperature difference may occur between the upper and lower layers of the room, or between the vicinity of the entrance of the room and the depth of the room, thereby impairing the comfort of the room. Disturbances in temperature distribution may also affect the physical condition of people. For this reason, when a situation occurs in which the temperature distribution is disturbed, it is preferable to perform appropriate air conditioning according to the situation.

In the present embodiment, the control device 3 determines whether the temperature distribution is disturbed by the operation of the ventilation device 4 or the opening of the room. When determining that the temperature distribution is disturbed, the control device 3 causes the circulation device 2 to perform the circulation operation. Circulation operation circulates or disturbs the air in the room. As a result, when the temperature distribution in the room is disturbed, the temperature distribution tends toward a uniform state. In this embodiment, the state in which the temperature distribution is disturbed is determined instead of detecting the state in which the temperature distribution is disturbed. As a result, it is possible to suppress the disturbance of the temperature distribution. This makes it possible to prevent uneven temperature distribution from occurring in the indoor air layer. In a room, it is possible to suppress the occurrence of an uncomfortable area that is too cold or too warm.

Effects of the present embodiment will be described.
(1) When the controller 3 determines that the temperature distribution is disturbed by the operation of the ventilation device 4 or the opening of the room, the controller 3 causes the circulation device 2 to perform the circulation operation. According to this configuration, the circulation operation is performed based on the fact that it is determined that the temperature distribution is disturbed. Thereby, uneven temperature distribution in the room can be suppressed.

(2) When the outdoor temperature TB is lower than the indoor temperature TA, the controller 3 determines that the indoor temperature change DT per unit time is negative and the temperature change DT is lower than the first predetermined value A1. At that time, it is determined that the temperature distribution is disturbed. When the outdoor temperature TB is higher than the indoor temperature TA, the temperature change DT is positive, and the temperature change DT is higher than the second predetermined value, the controller 3 assumes that the temperature distribution is disturbed. judge. According to this configuration, it is determined whether or not the temperature distribution is disturbed based on the indoor temperature change DT. In this way, it is possible to determine whether or not the temperature distribution is disturbed with a simple configuration.

(3) When the temperature difference between the indoor temperature TA and the outdoor temperature TB is greater than the third predetermined value and the ventilation device 4 is performing ventilation, the temperature distribution is disturbed. Judge the situation. According to this configuration, it is determined whether or not the temperature distribution will be disturbed based on the temperature difference between the indoor temperature TA and the outdoor temperature TB and the execution of ventilation. This makes it possible to accurately determine whether or not the temperature distribution is disturbed.

(4) When the outdoor temperature TB is lower than the indoor temperature TA, the refrigerant temperature change per unit time is negative, and the refrigerant temperature change is lower than the fourth predetermined value. , it is determined that the temperature distribution is disturbed. When the outdoor temperature TB is higher than the indoor temperature TA, the coolant temperature change is positive, and the coolant temperature change is higher than the fifth predetermined value, the control device 3 determines that the temperature distribution is disturbed. I judge. According to this configuration, it is determined whether or not the temperature distribution is disturbed based on the change in the coolant temperature. In this way, it is possible to determine whether or not the temperature distribution is disturbed with a simple configuration.

(5) When the outdoor temperature TB is higher than the indoor temperature TA and the temperature difference between the outdoor temperature TB and the indoor temperature TA is equal to or greater than a seventh predetermined value when executing the circulation operation, the control device 3 The angle of the louver 7A is adjusted to an angle larger than the first angle R1 with reference to the lower limit angle R0. When the outdoor temperature TB is lower than the indoor temperature TA and the temperature difference between the outdoor temperature TB and the indoor temperature TA is equal to or greater than an eighth predetermined value in executing the circulation operation, the controller 3 controls the louver 7A. The angle is adjusted to an angle smaller than the second angle R2 with reference to the lower limit angle R0.

When the outdoor temperature TB is higher than the indoor temperature TA, air tends to accumulate in the upper layers of the room. In the above configuration, in such a case, since the air is discharged upward, the air accumulated in the upper layer of the room can be quickly circulated. Also, when the outdoor temperature TB is lower than the indoor temperature TA, air tends to accumulate in the lower layers of the room. In the above configuration, in such a case, since the air is discharged downward, the air accumulated in the lower layer of the room can be quickly circulated.

(6) When the control device 3 receives a command from the wind direction control device 9 and determines that the temperature distribution is disturbed, the angle of the louver 7A is adjusted to the angle of the louver 7A set in the command. The angle is set between the angle and the angle of the louver 7A set in the circulation operation.

According to this configuration, when the angle of the louver 7A is set based on the information input to the wind direction control device 9 and it is determined that the temperature distribution is disturbed, the angle of the louver 7A is set to Effective circulation can be achieved without significantly changing the set angle.

<Second embodiment>
The air conditioning system 1 of the second embodiment will be described with reference to FIG.
In the air conditioning system 1 of the present embodiment, the same reference numerals are given to the same components as the air conditioner 10 of the first embodiment, and the description thereof is omitted. The air-conditioning system 1 of the present embodiment differs from the air-conditioning system 1 of the first embodiment in that it has a configuration that interlocks with the ventilator 4 .

The air conditioning system 1 includes a circulation device 2 , a control device 3 that controls the operation of the circulation device 2 , and a ventilation device 4 . The circulation device 2 preferably has a wind direction adjusting section 7 . The circulation device 2 may comprise an operating device 8 . The air conditioning system 1 of this embodiment has an air conditioner 10 as a circulation device 2 .

The control device 3 of the air conditioning system 1 may be configured separately from the control device 3 incorporated in the circulation device 2 , or may be configured integrally with the control device 3 incorporated in the circulation device 2 . In this embodiment, the control device 3 of the air conditioning system 1 is integrated with the control device 3 incorporated in the circulation device 2 .

The air conditioner 10 includes a control device 3 , an indoor heat exchanger 11 , an outdoor heat exchanger 12 and a compressor 13 . Furthermore, the air conditioner 10 includes an expansion valve 14 . Air conditioner 10 includes a refrigerant circuit 20 . The refrigerant circuit 20 includes an indoor heat exchanger 11, an outdoor heat exchanger 12, a compressor 13, an expansion valve 14, a switching valve 15, and a refrigerant pipe 16 connecting these. Compressor 13 compresses the refrigerant. The expansion valve 14 expands the refrigerant. Furthermore, the air conditioner 10 includes a ventilator 4 . Furthermore, the air conditioner 10 may include an operating device 8 . Furthermore, the air conditioner 10 may include a notification device 19 .

The operating device 8 may have the following configuration in addition to the configuration of the first embodiment.
The operating device 8 receives an input for operating the ventilator 4 (hereinafter referred to as "ventilation start input"). The operation device 8 transmits a command based on the ventilation start input (hereinafter referred to as “ventilation command”) to the ventilator 4 and the control device 3 . Thereby, the operation device 8 notifies the air conditioner 10 that ventilation has started.

The ventilation device 4 is configured as a separate device from the air conditioner 10 . The ventilator 4 includes at least one of indoor air exhaust and outdoor air supply. The ventilation device 4 includes a fan 31 , a drive unit 32 that operates the fan 31 , a ventilation control device 33 , and a drive switch 34 . The drive unit 32 has a motor. The drive unit 32 drives the fan 31 .

The ventilation control device 33 receives ventilation commands from the operating device 8 .
The ventilation control device 33 operates the drive unit 32 based on the ventilation command of the operation device 8 or the ON operation of the drive switch 34 . Specifically, the ventilation control device 33 issues a drive command to the drive unit 32 as a command for rotating the fan 31 .

When issuing a drive command to the drive unit 32 , the ventilation control device 33 outputs information corresponding to the drive command to the control device 3 of the air conditioner 10 . In this manner, the ventilation control device 33 transmits a signal indicating the operating state of the ventilation device 4 to the air conditioner 10 .

The controller 3 of the air conditioner 10 receives a signal indicating the operating state of the ventilator 4 from the ventilator 4 and determines that the temperature distribution is disturbed.
Further, the control device 3 receives a command (ventilation command) from the operation device 8 and determines that the temperature distribution is disturbed.

When the temperature difference between the indoor temperature TA and the outdoor temperature TB is smaller than the sixth predetermined value, the control device 3 controls the air conditioner regardless of whether or not it determines that the temperature distribution is disturbed. 10 does not execute circulation operation.

Effects of the present embodiment will be described.
The air conditioner 10 of the present embodiment has at least the effect (1) of the first embodiment among the effects described above for the air conditioner 10 of the first embodiment. In addition, the air conditioner 10 has the following effects.

(1) The controller 3 receives a signal indicating the operating state of the ventilator 4 from the ventilator 4 and determines that the temperature distribution is disturbed.
According to this configuration, it is determined whether or not the temperature distribution is disturbed based on the information indicating whether or not the ventilator 4 is in operation. In this way, it is possible to determine whether or not the temperature distribution is disturbed with a simple configuration.

(2) The operation device 8 receives an input to operate the ventilation device 4 and transmits a command based on the input to the ventilation device 4 and the control device 3 . By receiving a command from the operation device 8, the control device 3 determines that the temperature distribution is disturbed. According to this configuration, it is determined whether or not the temperature distribution will be disturbed based on the input for operating the ventilation device 4 in the operating device 8 . In this way, it is possible to determine whether or not the temperature distribution is disturbed with a simple configuration.

(3) When the temperature difference between the indoor temperature TA and the outdoor temperature TB is smaller than the sixth predetermined value, the control device 3 determines whether or not the temperature distribution is disturbed. The circulation device 2 is not made to perform the circulation operation.

According to this configuration, the circulation operation is not performed when the temperature difference between the indoor temperature TA and the outdoor temperature TB is smaller than the sixth predetermined value in a situation where it is determined that the temperature distribution is disturbed. As a result, useless circulation operation, which is performed when unevenness in temperature distribution is unlikely to occur, can be suppressed.

<Modification>
The air conditioner 10 of the present disclosure may be in the form of the modifications shown below, for example, in addition to the above-described embodiments, or may be in the form of a combination of at least two mutually consistent modifications.

- The situation in which the temperature distribution is disturbed may be determined by detecting whether or not the room is open. For example, the opening of the room may be detected by at least one of a sensor provided on the door and a sensor provided on the window. When the controller 3 detects that the room is open, it determines that the temperature distribution is disturbed.

・As described above, the embodiment of the air conditioner 10 has been described. It will be understood.

A1 First predetermined value DRT Refrigerant temperature change DT Temperature change R1 First angle R2 Second angle TA Indoor temperature TB Outdoor temperature 1 Air conditioning system 2 Circulation device 3 Control device 4 Ventilation device 7... Air direction adjusting unit 7A... Louver 8... Operating device 9... Air direction operating device

Claims (9)

”
In an air conditioning system (1) comprising a ventilation device (4), a circulation device (2), and a control device (3) for controlling the operation of the circulation device (2),
The control device (3) causes the circulation device (2) to perform a circulation operation when determining that the operation of the ventilation device (4) or the opening of the room causes a disturbance in the temperature distribution. The control device (3)
When the outdoor temperature (TB) is lower than the indoor temperature (TA), the indoor temperature change (DT) per unit time is negative, and the temperature change (DT) is lower than the first predetermined value. or when the outdoor temperature (TB) is higher than the indoor temperature (TA), the temperature change (DT) is positive and the temperature change (DT) is higher than a second predetermined value 2. The air conditioning system according to claim 1, wherein the air conditioning system of claim 1 determines that the temperature distribution is disturbed. The control device (3)
When the temperature difference between the indoor temperature (TA) and the outdoor temperature (TB) is greater than the third predetermined value and ventilation is being performed by the ventilator (4), the temperature distribution is disturbed. The air conditioning system according to claim 1 or 2. The control device (3)
When the outdoor temperature (TB) is lower than the indoor temperature (TA), the coolant temperature change per unit time is negative, and the coolant temperature change is lower than a fourth predetermined value, or When the outdoor temperature (TB) is higher than the indoor temperature (TA), the coolant temperature change is positive, and the coolant temperature change is higher than a fifth predetermined value, the temperature distribution is disturbed. The air conditioning system according to any one of claims 1 to 3, wherein the situation is determined to occur. The control device (3) determines that the temperature distribution is disturbed by receiving a signal indicating the operating state of the ventilation device (4) from the ventilation device (4). An air conditioning system according to any one of the preceding claims. further comprising an operating device 8 that receives an input to operate the ventilator (4) and transmits a command based on the input to the ventilator (4) and the control device (3);
6. The air conditioning system according to claim 5, wherein the control device (3) receives the command from the operation device 8 and determines that the temperature distribution is disturbed. The control device (3)
When the temperature difference between the indoor temperature (TA) and the outdoor temperature (TB) is smaller than a sixth predetermined value, regardless of whether or not it is determined that the temperature distribution is disturbed, the circulation device 7. The air conditioning system according to claim 5 or 6, wherein (2) does not execute the circulation operation. The circulation device (2) has a wind direction adjusting section (7) having a louver (7A) for adjusting the wind direction,
The control device (3)
When executing the circulation operation,
When the outdoor temperature (TB) is higher than the indoor temperature (TA) and the temperature difference between the outdoor temperature (TB) and the indoor temperature (TA) is equal to or greater than a seventh predetermined value, the angle of the louver (7A) is adjusted to an angle larger than the first angle (R1) with reference to the lower limit angle (R0),
When the outdoor temperature (TB) is lower than the indoor temperature (TA) and the temperature difference between the outdoor temperature (TB) and the indoor temperature (TA) is equal to or greater than an eighth predetermined value, the angle of the louver (7A) is adjusted to an angle smaller than the second angle (R2) with respect to the lower limit angle (R0). further comprising a wind direction operation device (9) that receives an input for setting the angle of the louver (7A) and transmits a command based on the input to the circulation device (2) and the control device (3);
When the control device (3) receives the command and determines that the temperature distribution is disturbed, the control device (3) changes the angle of the louver (7A) to the angle set by the command. 9. The air conditioning system according to claim 8, wherein the angle is set between the angle of 7A) and the angle of the louver (7A) set in the circulation operation.

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