JP7576771B2 - Air Conditioning System - Google Patents

Description

The present invention relates to an air conditioning system.

Patent Document 1 discloses an indoor unit that extends the detection time as much as possible when a detection sensor is activated by a power storage unit used as an emergency power source during a power outage. This indoor unit includes a casing, a heat exchanger through which a flammable refrigerant flows, a power storage unit used as an emergency power source when there is no power supply from the commercial power source, a detection sensor that detects refrigerant leakage, and a control unit that controls the supply of electricity to the detection sensor from the commercial power source or the power storage unit. The control unit controls the supply of electricity from the power storage unit to the detection sensor so as to activate the detection sensor intermittently.

JP 2015-117931 A

The present invention provides an air conditioning system that can efficiently operate a device for preventing refrigerant leakage using power from a power storage unit when there is no power supply from a commercial power source.

The air conditioning system of the present disclosure comprises a refrigeration cycle that circulates a slightly flammable refrigerant or a flammable refrigerant, an indoor unit installed in an indoor space and provided with a heat exchanger connected to the refrigeration cycle, a refrigerant sensor that detects refrigerant leaking from the indoor unit, a ventilation device that ventilates the indoor space, a power storage unit that is charged by a commercial power source, and a control unit, wherein the refrigerant sensor and the ventilation device are operated by a commercial power source, and the control unit operates the ventilation device using power from the power storage unit when the supply of the commercial power source is stopped, and after operating the ventilation device, determines whether the refrigerant sensor is functioning normally, and if it is determined that the refrigerant sensor is functioning normally, continues operation of the ventilation device for a predetermined period of time .

According to the present invention, when there is no power supply from the commercial power source, the power storage unit can be used to efficiently drive the device for preventing refrigerant leakage.

A block diagram showing the configuration of an air conditioning system 1 according to a first embodiment. FIG. 1 shows a configuration of an air conditioning system 1 in an indoor space. A flowchart showing the operation of the air conditioning system 1 when the commercial power supply is in a power outage state. A flowchart showing the operation of the air conditioning system 1 when the commercial power supply is in a power outage state. A block diagram showing a configuration of an air conditioning system 1 according to a second embodiment. A flowchart showing the operation of the air conditioning system 1 when the commercial power supply is in a power outage state.

(The knowledge and other information that formed the basis of this disclosure)
At the time the inventors came up with the idea of this disclosure, there was technology available for extending as long as possible the detection time when a detection sensor in an indoor unit of an air conditioning system 1 is activated by a power storage unit used as an emergency power source to prevent refrigerant leakage in the event of a power outage.
This indoor unit is equipped with a heat exchanger through which a flammable refrigerant flows, a battery serving as an electricity storage unit used as an emergency power source when there is no power supply from the commercial power source, a detection sensor for detecting leakage of the flammable refrigerant, and a control device serving as a control unit for controlling the supply of electricity from the commercial power source or the battery to the detection sensor. The control device controls the supply of electricity from the battery to the detection sensor so as to activate the detection sensor intermittently.

Incidentally, when commercial power is cut off (so-called power outage) due to an earthquake or the like, there is a risk of refrigerant leaking due to damage to the refrigerant piping, etc., so when the commercial power is cut off, there is a high need to operate the refrigerant sensor and ventilation device from an external power source. However, because the ventilation device consumes more power than the refrigerant sensor, there is a risk that these devices for preventing refrigerant leakage cannot be operated for a long period of time using an external power source.
In view of this, the present disclosure provides an air conditioning system 1 that is capable of efficiently driving a ventilator using power from a power storage unit when power supply from a commercial power source is interrupted.

Hereinafter, the embodiments will be described in detail with reference to the drawings. However, more detailed explanation than necessary may be omitted. For example, detailed explanation of already well-known matters or duplicate explanation of substantially the same configuration may be omitted. This is to avoid the following explanation becoming more redundant than necessary and to facilitate understanding by those skilled in the art.
It should be noted that the accompanying drawings and the following description are provided to enable those skilled in the art to fully understand the present disclosure, and are not intended to limit the subject matter described in the claims.

(Embodiment 1)
Hereinafter, the first embodiment will be described with reference to FIGS. 1 to 4. FIG.
[1-1. Configuration]
[1-1-1. Configuration of air conditioning system]

FIG. 1 is a block diagram showing the configuration of an air conditioning system 1 according to this embodiment.
FIG. 2 is a diagram showing the configuration of the air conditioning system 1 in an indoor space 70.
The air conditioning system 1 includes a refrigeration cycle formed by an indoor heat exchanger 29 and a pressure reducing device housed in the indoor unit 11, and a compressor, a pressure reducing device, an outdoor heat exchanger, and the like housed in the outdoor unit 10. The air conditioning system 1 conditions an indoor space 70, which is a conditioned space in which the indoor unit 11 is provided, by circulating a refrigerant through this refrigeration cycle.
In this embodiment, R32, which is a mildly flammable refrigerant, is used as the refrigerant for the air conditioning system 1. However, the refrigerant is not limited to this, and various alternatives to fluorocarbons, such as hydrocarbons and ammonia, may be used as the refrigerant for the air conditioning system 1.

As shown in Figures 1 and 2, the air conditioning system 1 of this embodiment is equipped with an outdoor unit 10 and an indoor unit 11, and is configured by connecting the outdoor unit 10 and the indoor unit 11 by refrigerant pipes 2 and 4.
The outdoor unit 3 includes a compressor, a heat source side heat exchanger, an expansion valve, and a switching valve for switching between a heating operation and a cooling operation. The outdoor unit 3 may also include an accumulator, a pressure sensor, etc.

The indoor unit 11 is installed in an indoor space 70 and conditions the air of the indoor space 70. In other words, the indoor space 70 is a space to be conditioned by the indoor unit 11.
The air conditioning system 1 performs cooling operation or heating operation for the indoor space 70. For this reason, refrigerant flows through two refrigerant pipes 2, 4 between the outdoor unit 3 and the indoor unit 11. High-pressure gas refrigerant flows through one of the refrigerant pipes 2, 4, and low-pressure gas or liquid refrigerant flows through the other. The refrigerant pipes 2, 4 each branch off and are connected to a refrigerant circuit 21 provided in the indoor unit 11. The direction in which the refrigerant flows through the refrigerant pipes 2, 4 is reversed during cooling operation and heating operation of the air conditioning system 1.

The air conditioning system 1 is provided with a refrigerant leakage detection sensor 13, which is a detection sensor that detects refrigerant. The refrigerant leakage detection sensor 13 detects refrigerant leaking from the refrigerant circuit 21, the connection between the refrigerant circuit 21 and the refrigerant pipes 2, 4, etc.
In this embodiment, the refrigerant leakage detection sensor 13 is installed in the indoor space 70. When the refrigerant used in the air conditioning system 1 is a gas having a higher specific gravity than air, it is preferable that the refrigerant leakage detection sensor 13 be installed in a lower part of the indoor space 70.
The refrigerant leakage detection sensor 13 may be disposed inside the housing of the indoor unit 11 .

The air conditioning system 1 is equipped with a ventilation device 14. This ventilation device 14 is a so-called mechanical ventilation device that uses a blower equipped with various types of fans such as an axial fan or a centrifugal fan, and ventilates the indoor space in which it is installed by using the fan.
The ventilation device 14 of the present embodiment is configured to exhaust the refrigerant that has leaked into the indoor space 70 to the outside of the indoor space 70 .

The ventilation device 14 is connected to a commercial AC power source 9 as a commercial power source via a power supply line 32. The commercial AC power source 9 is a power source connected to the ventilation device 14 in the indoor space 70. Therefore, AC 200V power is supplied to the ventilation device 14 from the commercial AC power source 9. The ventilation device 14 can be driven by this power.

The air conditioning system 1 of the present embodiment is provided with an external power supply kit 15 that is placed in the indoor space.
The external power supply kit 15 includes a power storage unit 52 that stores the supplied current. When the supply of current is stopped, the external power supply kit 15 discharges and supplies the stored power to each component of the air conditioning system 1.

The air conditioning system 1 is equipped with an alarm device 16. The alarm device 16 issues an alarm to the outside, and in this embodiment, reports various information to a management center according to the state of the air conditioning system 1. For example, if the operation of the refrigerant leakage detection sensor 13 or the ventilation device 14 cannot be confirmed, the alarm device 16 reports to the management center that these devices require repair.
The alarm device 16 may be configured to issue an alert not only to the outside, but also to people in the indoor space 70. In this case, the alarm device 16 may be provided integrally with a remote control device or the like capable of operating the air conditioning system 1.

The air conditioning system 1 is equipped with a control device 19. The control device 19 controls the operation of the air conditioning system 1. For example, the control device 19 controls the start and stop of the outdoor unit 10, controls the operation of the compressor and switching valve equipped in the outdoor unit 10, detects the operating status of the outdoor unit 10 and the indoor unit 11, etc.

[1-1-2. Configuration of indoor unit]
As shown in FIG. 2 , the indoor unit 11 includes an indoor heat exchanger 29 that constitutes the refrigerant circuit 21 , and an indoor fan 28 that sends air to the indoor heat exchanger 29 .

The indoor unit 11 is equipped with a refrigerant circuit 21 through which the refrigerant supplied from the outdoor unit 10 flows. The refrigerant circuit 21 includes, for example, an indoor heat exchanger 29, which is a user-side heat exchanger, and other piping.

The indoor unit 11 is connected to a commercial AC power supply 9 as a commercial power source by a power supply line 33. The commercial AC power supply 9 is a power source connected to the indoor unit 11 in the indoor space 70. This commercial AC power supply 9 is a power source common to the one connected to the ventilation device 14 described above. Therefore, AC 200V power is supplied to the indoor unit 11 from the commercial AC power supply 9.

In this embodiment, an example is described in which a commercial AC power source 9 of AC 200V is connected to the indoor unit 11, but this is not limited to the above, and other power sources such as AC 100V may be connected to the indoor unit 11. Similarly, the above-mentioned ventilation device 14 may be connected to other power sources such as AC 100V, not limited to AC 200V.

The indoor unit 11 is equipped with an indoor unit control unit 20. The indoor unit control unit 20 is equipped with a computer having a processor such as a CPU or MPU, and memory devices such as a ROM or RAM, and functions as a control unit that controls each part of the air conditioning system 1. The indoor unit control unit 20 may be realized by multiple processors or semiconductor chips.

The indoor unit control unit 20 includes a PCB (Printed Circuit Board) 22. The PCB 22 is a so-called printed circuit board, and the PCB 22 is a board on which a microcomputer, a processor, a power supply circuit, and the like that constitute the indoor unit control unit 20 are mounted.
The indoor unit control unit 20 controls the operation of the indoor unit 11 and each part of the electrically connected air conditioning system 1. For example, the indoor unit control unit 20 operates a fan motor of the indoor fan 28 using power supplied through a power supply line 33.

A remote control receiver or an operation panel may be connected to the PCB 22. In this case, the indoor unit control unit 20 changes the target temperature based on the operation of the remote control or the operation panel, and controls the operation of the indoor unit 11 according to the target temperature. The indoor unit control unit 20 may also have a function of transmitting data regarding the operating state to the control device 19.

A power supply line 34 is arranged between the PCB 22 and the refrigerant leakage detection sensor 13. The power supply line 34 branches the power supplied from the power supply line 33 and outputs it to the refrigerant leakage detection sensor 13. Therefore, the refrigerant leakage detection sensor 13 is supplied with AC 200V power.
A power supply line 33 is connected to the PCB 22. As a result, power of, for example, AC 200 V is supplied to the PCB 22 from the commercial AC power source 9.

The refrigerant leakage detection sensor 13 is connected to the PCB 22 by a signal line 41 .
The signal line 41 transmits a control signal generated by the PCB 22 to the refrigerant leakage detection sensor 13. The specific form of the signal line 41 is arbitrary, and may be, for example, a line that electrically connects the PCB 22 and the refrigerant leakage detection sensor 13, or a communication line that transmits a control signal based on a predetermined communication protocol. The signal line 41 may also be connected by a wireless communication line. Note that in this embodiment, the forms of other signal lines described below are the same as the form of the signal line 41.

The refrigerant leakage detection sensor 13 may be connected to the commercial AC power supply 9 without passing through the PCB 22. In this case, the refrigerant leakage detection sensor 13 may be connected to the PCB 22 wirelessly or by wire, and the refrigerant leakage detection sensor 13 may be controlled by the PCB 22.
In this case, the refrigerant leakage detection sensor 13 may be equipped with a control unit, and the refrigerant leakage detection sensor 13 may be controlled by the control unit.

The control signal is a signal that instructs the refrigerant leakage detection sensor 13 to be driven or stopped via this signal line 41. Upon receiving this control signal, the refrigerant leakage detection sensor 13 is driven to detect refrigerant leakage, or is stopped from being driven.
Also, the indoor unit control unit 20 monitors the detection state of the refrigerant leakage detection sensor 13 via this signal line 41, and detects refrigerant leakage using the refrigerant leakage detection sensor 13. Furthermore, the indoor unit control unit 20 determines via this signal line 41 whether the refrigerant leakage detection sensor 13 is normally detecting refrigerant leakage.

The PCB 22 is connected to the ventilation device 14 by a signal line 43. The signal line 43 transmits a control signal generated by the indoor unit control unit 20 to the ventilation device 14. This control signal is a signal by which the indoor unit control unit 20 instructs the ventilation device 14 to start or stop operation. By receiving this control signal, the ventilation device 14 operates to ventilate the indoor space 70 or stops ventilation of the indoor space 70.

A power supply line 35 is arranged between the PCB 22 and the external power supply kit 15. The power supply line 35 branches the power supplied from the power supply line 33 and outputs it to the external power supply kit 15. Therefore, AC 200V power is supplied to the external power supply kit 15.

The external power supply kit 15 is connected to the PCB 22 via a signal line 44. The indoor unit control unit 20 controls the external power supply kit 15 by sending a control signal via this signal line 44.

The indoor unit control unit 20 includes a memory unit 24 that stores various data related to the operation of each part of the air conditioning system 1 and the operation of the indoor unit 11 .
[1-1-3. External power supply kit configuration]
As shown in FIG. 1 , the external power supply kit 15 includes an external power supply control unit 50 , a power storage unit 52 , and a charging port 54 .

The power storage unit 52 is charged by a current supplied from the PCB 22 through the power supply line 35. The power storage unit 52 stores electricity and maintains a charged state while a current is supplied from the commercial AC power source 9 via the PCB 22.
Furthermore, the power storage unit 52 discharges when the supply of current stops, and supplies power to each unit connected to the external power supply kit 15 via the multiple power supply lines 36. The supply of current stops when the output of the PCB 22 stops, for example, when the commercial AC power supply 9 experiences a power outage.

In this embodiment, the refrigerant leak detection sensor 13, the ventilation device 14, and the alarm device 16 are connected to the external power supply kit 15 via the respective power supply lines 36. The power storage unit 52 of the external power supply kit 15 supplies power to these devices, for example, when the commercial AC power supply 9 experiences a power outage. As a result, in the air conditioning system 1, even when the commercial AC power supply 9 experiences a power outage, the refrigerant leak detection sensor 13, the ventilation device 14, and the alarm device 16 can be driven by power from the external power supply kit 15.

The power storage unit 52 stores power in a secondary battery or a capacitor. If the power storage unit 52 is configured to include a secondary battery such as a metal hydride battery, a lithium battery, or a lithium ion battery, the storage capacity can be increased. Furthermore, if the power storage unit 52 is configured to include a capacitor, rapid charging and discharging is possible. Furthermore, it is possible to omit complex circuit configurations such as charge and discharge control circuits required for secondary batteries, which is advantageous in terms of cost. It is desirable that the secondary battery or capacitor of the power storage unit 52 can store an amount of power that is sufficient to operate each device connected to the power storage unit 52 via the power supply line 36 for a predetermined period of time.

The charging port 54 provided in the external power supply kit 15 is for connecting an external battery, generator, etc., to supply power to the power storage unit 52. In this embodiment, for example, in the event of a long-term power outage of the commercial AC power supply 9, it is possible to supply power to the power storage unit 52 by connecting a power source other than the commercial AC power supply 9, such as a battery, to the charging port 54.

As described above, the external power supply kit 15 includes an external power supply control unit 50. Like the indoor unit control unit 20, the external power supply control unit 50 includes a computer having a processor such as a CPU or MPU, and a memory device such as a ROM or RAM. The external power supply control unit 50 may be realized by multiple processors or semiconductor chips.

The external power supply control unit 50 functions as a control unit that controls each unit of the external power supply kit 15 , such as the power storage unit 52 .
As described above, the external power supply kit 15 is connected to the PCB 22 via the signal line 44. The external power supply control unit 50 receives a predetermined signal via this signal line 44 and functions as a determination unit that determines whether the commercial AC power supply 9 is in a state where it can supply power, i.e., whether the commercial power supply is in a power outage state.

In this embodiment, the refrigerant leakage detection sensor 13 , the ventilation device 14 , and the alarm device 16 are connected to the external power supply kit 15 via respective signal lines 45 .
When the current supplied from the commercial AC power source 9 stops, the power storage unit 52 discharges, and the external power supply control unit 50 supplies power to each unit connected to the external power supply kit 15 via the multiple power supply lines 36, the external power supply control unit 50 functions as a control unit that controls each unit connected to the external power supply kit 15 via each signal line 45.

Specifically, the external power supply control unit 50 transmits a control signal generated by the external power supply control unit 50 to the refrigerant leakage detection sensor 13 via a signal line 45 .
The control signal is a signal that instructs the refrigerant leakage detection sensor 13 to be driven or stopped via this signal line 45. Upon receiving this control signal, the refrigerant leakage detection sensor 13 is driven to detect refrigerant leakage, or is stopped from being driven.

In this embodiment, the external power supply control unit 50 activates the refrigerant leak detection sensor 13 when the ventilation device 14 is stopped, and stops the refrigerant leak detection sensor 13 when the ventilation device 14 is operating.
When the ventilation device 14 is operating, the leaked refrigerant is diffused by the ventilation device 14 in the indoor space 70. This dilutes the refrigerant concentration in the indoor space 70. Therefore, the operation of the refrigerant leakage detection sensor 13 can be stopped, and the amount of power consumption of the power storage unit 52 can be effectively reduced.

Furthermore, when a predetermined time or more has elapsed since the start of power supply from the power storage unit 52 to the refrigerant leakage detection sensor 13, the external power supply control unit 50 intermittently drives the refrigerant leakage detection sensor 13.
More specifically, the refrigerant concentration in the indoor space 70 remains diluted for a predetermined time after the operation of the ventilation device 14 is stopped. For this reason, in the air conditioning system 1, it becomes possible to stop the operation of the refrigerant leakage detection sensor 13 for a predetermined time after the operation of the ventilation device 14 is stopped. In the air conditioning system 1, by stopping the operation of the refrigerant leakage detection sensor 13 for a predetermined time, the amount of power consumed by the power storage unit 52 can be effectively reduced.

Moreover, it is further preferable that the external power supply control unit 50 intermittently drives the refrigerant leak detection sensor 13 when a predetermined time or more has elapsed since the start of the power supply from the power storage unit 52 to the refrigerant leak detection sensor 13. This allows the air conditioning system 1 to effectively reduce the amount of power consumed by the power storage unit 52.

In addition, when the external power supply control unit 50 drives the refrigerant leak detection sensor 13 intermittently, it controls the ratio of the stop time of the refrigerant leak detection sensor 13 to the drive time of the refrigerant leak detection sensor 13 to become longer as a predetermined time elapses from the start of the intermittent drive.
More specifically, the longer the time that has passed since the power supply from the commercial AC power source 9 was stopped, the lower the possibility of the refrigerant leaking into the indoor space 70. For this reason, in the air conditioning system 1, by implementing control such that the proportion of the stopped time of the refrigerant leakage detection sensor 13 becomes longer over time as the time passes since the commercial power source was stopped as described above, the amount of power consumption of the power storage unit 52 can be effectively reduced.

Furthermore, the external power supply control unit 50 monitors the detection state of the refrigerant leakage detection sensor 13 via this signal line 45, and detects refrigerant leakage using the refrigerant leakage detection sensor 13. In addition, the external power supply control unit 50 determines via this signal line 45 whether the refrigerant leakage detection sensor 13 is normally detecting refrigerant leakage.

The external power supply control unit 50 is connected to the ventilation device 14 by a signal line 45. The signal line 45 transmits a control signal generated by the external power supply control unit 50 to the ventilation device 14. This control signal is a signal by which the external power supply control unit 50 instructs the ventilation device 14 to start or stop operation. Upon receiving this control signal, the ventilation device 14 operates to ventilate the indoor space 70 or stops ventilation of the indoor space 70. In other words, the external power supply control unit 50 controls the operation of the ventilation device 14 via this signal line 45.

The external power supply control unit 50 is connected to the alarm device 16 via a signal line 45. The signal line 45 transmits a control signal generated by the external power supply control unit 50 to the alarm device 16. This control signal instructs the alarm device 16 to notify the management center that repairs are required if the operation of the refrigerant leakage detection sensor 13 or the ventilation device 14 cannot be confirmed. By receiving this control signal, the alarm device 16 notifies the management center that repairs are required.
Furthermore, the external power supply control unit 50 transmits a control signal to the alarm device 16 via the signal line 45, instructing the alarm device 16 to notify the management center that the refrigerant leakage detection sensor 13 has detected the refrigerant. By receiving this control signal, the alarm device 16 notifies the management center that the refrigerant leakage detection sensor 13 has detected the refrigerant.

The external power supply control unit 50 includes a memory unit 56 that stores various data related to the control of each part of the external power supply kit 15 and each part connected to the external power supply kit 15. For example, the memory unit 56 stores the floor area S ( ^m2 ), leakage height H (m), LFL (vol%), etc., and the external power supply control unit 50 acquires these values from the memory unit 56.
In this embodiment, various numerical values such as floor area S (m ² ), leakage height H (m), LFL (vol %), etc. are input into the storage unit 56 by an operator when the air conditioning system 1 is installed.

[1-2. Operation]
The operation of the air conditioning system 1 configured as above will be described below.
3 and 4 are flowcharts showing the operation of the air conditioning system 1 when the commercial AC power supply 9 is in a power outage state.
As described above, in the air conditioning system 1, the indoor unit 11, the refrigerant leak detection sensor 13, the ventilation device 14, the external power supply kit 15, and the alarm device 16 are supplied with AC 200 V power from the commercial AC power supply 9.

However, there may be cases where a power outage occurs due to, for example, a lightning strike, and the power supply from the commercial AC power supply 9 to the air conditioning system 1 is stopped, resulting in a so-called blackout.
In this way, when the commercial AC power supply 9 is in a power outage state, the external power supply control unit 50 detects that the power supply from the PCB 22 to the external power supply kit 15 has stopped. Then, the external power supply control unit 50 starts supplying power from the power storage unit 52 to the ventilation device 14, and drives the ventilation device 14 to ventilate at a predetermined ventilation volume (step SA1).

In this way, by quickly activating the ventilation device 14 when a power outage occurs, regardless of whether or not the refrigerant is detected by the refrigerant leak detection sensor 13, even if a refrigerant leak occurs when a power outage occurs, the air conditioning system 1 can reliably respond to the refrigerant leak without delay. Therefore, the air conditioning system 1 can suppress an increase in the concentration of the leaked refrigerant in the indoor space 70.

After that, the external power supply control unit 50 determines whether the commercial AC power supply 9 has recovered from the power outage (step SA2). Specifically, the external power supply control unit 50 determines whether the commercial AC power supply 9 is in a power outage state by acquiring a predetermined signal via the signal line 44 connected to the PCB 22.
In addition, in step SA2, the external power supply control unit 50 may temporarily suspend the ventilation device 14.

When the external power supply control unit 50 determines that the commercial AC power supply 9 has recovered from the power outage (step SA2: YES), the external power supply control unit 50 stops the power supply from the storage unit 52 to the ventilation device 14 and resumes the power supply from the commercial AC power supply 9 to each unit.
Next, the external power supply control unit 50 determines whether the refrigerant leakage detection sensor 13 is functioning normally (step SA3).
Specifically, the external power supply control unit 50 communicates with the refrigerant leakage detection sensor 13 via the signal line 45 and determines whether or not a normal signal can be received from the refrigerant leakage detection sensor 13 .

If it is determined that the refrigerant leak detection sensor 13 is functioning normally (step SA3: YES), that is, if a normal signal has been received from the refrigerant leak detection sensor 13, the external power supply control unit 50 drives the refrigerant leak detection sensor 13 and determines whether the refrigerant leak detection sensor 13 has detected a refrigerant leak (step SA4). Specifically, the external power supply control unit 50 obtains the detection result of the refrigerant leak detection sensor 13 via the signal line 45 and determines whether the refrigerant leak detection sensor 13 has detected a refrigerant.

If the refrigerant leakage detection sensor 13 detects a refrigerant leakage (step SA4: YES), the external power supply control unit 50 continues to operate the ventilation device 14 and activates the alarm device 16 (step SA5). The alarm device 16 notifies the management center that the refrigerant leakage detection sensor 13 has detected a refrigerant.
Then, the refrigerant leakage portion is repaired by a worker instructed by the management center (step SA6).

In step SA4, if the refrigerant leak detection sensor 13 does not detect a refrigerant leak (step SA4: NO), the external power supply control unit 50 stops the ventilation device 14 (step SA7).Then, the external power supply control unit 50 returns each part of the air conditioning system 1 to normal operation (step SA8).

If it is determined in step SA3 that the refrigerant leakage detection sensor 13 is not functioning normally (step SA3: NO), the external power supply control unit 50 continues to drive the ventilation device 14 and drives the alarm device 16 (step SA5). The alarm device 16 notifies the management center that the refrigerant leakage detection sensor 13 has detected a refrigerant.
Then, the refrigerant leakage portion is repaired by a worker instructed by the management center (step SA6).

Note that, in step SA2, if the external power supply control unit 50 determines that the commercial AC power supply 9 has recovered from a power outage (step SA2: YES), control of each part of the air conditioning system 1 may be switched from the external power supply control unit 50 to the PCB 22.

If the external power supply control unit 50 determines in step SA2 that the commercial AC power supply 9 has not recovered from the power outage (step SA2: NO), the external power supply control unit 50 determines whether the refrigerant leak detection sensor 13 is functioning normally (step SA9).

If it is determined that the refrigerant leak detection sensor 13 is functioning normally (step SA9: YES), i.e., if a normal signal is received from the refrigerant leak detection sensor 13, the external power supply control unit 50 continues to operate the ventilation device 14 for a predetermined time (step SA10).

Here, the ventilation time, which is the predetermined time for which the external power supply control unit 50 continues to operate the ventilation device 14 in step SA10, will be described.
When the commercial AC power supply 9 experiences a power outage and the refrigerant leakage detection sensor 13 determines that a refrigerant leakage is being detected normally, the external power supply control unit 50 determines the time for which the ventilation device 14 operates, i.e., the ventilation time (predetermined time), using the remaining power amount in the storage unit 52 and the set times T1 and T2.

The set time T1 is calculated using the following formula (1).
T1=Vr/M (1)
In formula (1), T1 (s) is the ventilation time, Vr (m ³ ) is a predetermined volume in the indoor space 70, and M (m ³ /s) is the ventilation amount of the ventilation device 14 per unit time.
That is, T1 is the time during which the ventilation device 14 can ventilate the air of the indoor volume, which is the volume of the indoor space 70 (the time required to ventilate the air of the indoor volume).
In this embodiment, Vr (m ³ ) is determined by the product of the floor area S (m ² ) and the leakage height H (m), where the leakage height H is the height from the floor surface of the indoor space 70 to the point where the refrigerant is assumed to leak.

The set time T2 is a ventilation time by the ventilation device 14 until the concentration in the indoor space 70 reaches a concentration (½ LFL) that is half the LFL (Lower Flammability Limit).
Although the set time T2 is calculated as a time to obtain 1/2 LFL relative to the indoor volume, the present disclosure is not limited to this. For example, assuming that refrigerant leaks into the indoor space 70 during a power outage of the commercial AC power source 9, ventilation may be performed until the refrigerant concentration in the indoor space 70 becomes equal to or lower than a predetermined concentration. The time to obtain the refrigerant concentration in the indoor space 70 becomes equal to or lower than a predetermined concentration may be, for example, the ventilation time until the refrigerant concentration becomes less than 1/4 LFL relative to the indoor volume.
In addition, the lower limit of the ventilation time by the ventilation device 14 is not limited to T2 described above, and may be obtained from a necessity determination tool for an R32 safety device provided in the indoor space 70, for example.

The external power supply control unit 50 sets the set time T1 as the upper limit of the ventilation time by the ventilation device 14, and sets the set time T2 as the lower limit of the ventilation time by the ventilation device 14. The external power supply control unit 50 then determines the ventilation time between the set times T1 and T2 in accordance with the remaining power amount in the power storage unit 52, and drives the ventilation device 14 for that ventilation time.
The set times T1 and T2 may be calculated taking into consideration the leakage speed of the refrigerant.

The external power supply control unit 50 also drives the ventilation device 14 intermittently when a predetermined time has elapsed since the start of the power supply from the power storage unit 52 to the ventilation device 14. In other words, the external power supply control unit 50 intermittently supplies power from the power storage unit 52 to the ventilation device 14 when a predetermined time has elapsed since the start of the power supply from the power storage unit 52 to the ventilation device 14.

In addition, when the external power control unit 50 drives the ventilation device 14 intermittently, the external power control unit 50 stops the ventilation device 14 for a longer period of time as time passes. That is, the external power control unit 50 lengthens the time for which the power supply from the power storage unit 52 to the ventilation device 14 is stopped as the number of times the ventilation device 14 is operated increases.
When driving the ventilation device 14 intermittently, the external power supply control unit 50 may reduce the ventilation volume of the ventilation device 14 as time passes.

4, when the ventilation time has elapsed, the external power supply control unit 50 stops the ventilation device 14 (step SA11). Furthermore, when a predetermined time has elapsed since the ventilation device 14 was stopped, the external power supply control unit 50 activates the refrigerant leakage detection sensor 13 (step SA12).
More specifically, immediately after the operation of the ventilation device 14 is stopped, the refrigerant concentration in the indoor space 70 is diluted, so there is little need to drive the refrigerant leakage detection sensor 13. Therefore, in the air conditioning system 1, in step SA12, by not supplying electricity to the refrigerant leakage detection sensor 13 immediately after the operation of the ventilation device 14 is stopped, the amount of electricity supplied to the refrigerant leakage detection sensor 13 can be reduced.

In addition, by activating the refrigerant leak detection sensor 13 a predetermined time after ventilation by the ventilation device 14, if a refrigerant leak occurs, the refrigerant leak detection sensor 13 will detect the refrigerant leak while a predetermined amount of the refrigerant is retained. Therefore, in the air conditioning system 1, it is possible to prevent the refrigerant leak detection sensor 13 from failing to detect the leak, and also to shorten the operation time of the refrigerant leak detection sensor 13, thereby preventing a decrease in the amount of electricity stored in the power storage unit 52.

In this embodiment, the specified time between the stopping of the ventilation device 14 and the activation of the refrigerant leak detection sensor 13 is calculated from the refrigerant leak rate of 10 kg/h and the LFL.

As shown in FIG. 4, after driving the refrigerant leakage detection sensor 13, the external power supply control unit 50 determines whether or not the refrigerant leakage detection sensor 13 has detected a refrigerant leakage (step SA13).
If the refrigerant leakage detection sensor 13 detects a refrigerant leakage (step SA13: YES), the external power supply control unit 50 stops the operation of the refrigerant leakage detection sensor 13 and activates the ventilation device 14 and the alarm device 16 (step SA14). The alarm device 16 notifies the management center that the refrigerant leakage detection sensor 13 has detected a refrigerant.

As in step SA14, when the refrigerant leak detection sensor 13 detects a refrigerant leak, the external power supply control unit 50 drives the ventilation device 14, thereby diffusing the leaked refrigerant in the indoor space 70 and effectively diluting the concentration of the refrigerant in the air conditioning system 1.
Hereinafter, the operation of the ventilation device 14 continuously for a predetermined period of time as in step SA14 will be referred to as a first ventilation operation of the ventilation device 14.

In addition, in step SA14, the refrigerant leak detection sensor 13 and the ventilation device 14 are prevented from being driven simultaneously. This makes it possible for the air conditioning system 1 to prevent a decrease in the amount of electricity stored in the power storage unit 52.

When a predetermined time has elapsed since the first ventilation operation of the ventilation device 14 is performed, the external power supply control unit 50 causes the ventilation device 14 to perform so-called intermittent operation, in which the ventilation device 14 is alternately driven and stopped (step SA15).
As a result, in the air conditioning system 11, the decrease in the amount of power stored in the power storage unit 52 can be suppressed more effectively than if the ventilation device 14 were continuously driven.
Hereinafter, the intermittent operation of the ventilation device 14 that is performed after a predetermined time has elapsed since the first ventilation operation of the ventilation device 14 was performed will be referred to as a second ventilation operation of the ventilation device 14.

In the event that a refrigerant leak occurs, the amount of leaking refrigerant decreases over time. That is, in the air conditioning system 1, the amount of ventilation required decreases over time.
For this reason, in step SA15, the external power supply control unit 50 extends the stop time relatively to the drive time in the intermittent operation of the ventilation device 14 as time passes after driving the ventilation device 14. In other words, after a predetermined time has passed since the ventilation device 14 was caused to perform the second ventilation operation, the external power supply control unit 50 continues the intermittent operation of the ventilation device 14 while extending the time for which the ventilation device 14 is stopped relative to the second ventilation operation.

As a result, in the air conditioning system 1, the time for which the ventilation device 14 is operated can be shortened until the refrigerant leakage location is repaired, and a decrease in the amount of power stored in the power storage unit 52 can be suppressed.
Hereinafter, the operation of the ventilation device 14 in which the intermittent operation of the ventilation device 14 is continued after a predetermined time has elapsed since the second ventilation operation of the ventilation device 14 was performed, while extending the time that the ventilation device 14 is stopped compared to the second ventilation operation, is referred to as the third ventilation operation of the ventilation device 14.

Note that, instead of extending the stop time of the ventilation device 14 over time as described above, the external power supply control unit 50 may reduce the ventilation volume over time when the ventilation device 14 is driven. In this case, the amount of power consumed by the ventilation device 14 can be reduced, and the decrease in the amount of power stored in the power storage unit 52 can be suppressed.
Hereinafter, the operation of the ventilation device 14 in which the ventilation volume is reduced over time will be referred to as a fourth ventilation operation of the ventilation device 14.

Furthermore, the external power supply control unit 50 may cause the ventilation device 14 to extend the stop time of the ventilation device 14 relatively longer than the drive time and to reduce the ventilation volume of the ventilation device 14 over time. In other words, the external power supply control unit 50 may cause the ventilation device 14 to simultaneously perform the third ventilation operation and the fourth ventilation operation.

Then, the refrigerant leak location is repaired by a worker instructed by the management center (step SA16). When the worker has completed repairing the refrigerant leak location, the ventilation device 14 is stopped, for example, by the worker.

Even if the refrigerant leakage detection sensor 13 does not detect a refrigerant leakage in step SA13 (step SA13: NO), there is a risk that the refrigerant leakage speed is slow, that is, a so-called slow leak is occurring.
Therefore, in this embodiment, when there is a slow leak of refrigerant, if the refrigerant leak detection sensor 13 does not detect a refrigerant leak even after the time has passed until the refrigerant concentration in the indoor space 70 becomes half the LFL concentration (1/2LFL) due to the slow leak (SA17: YES, SA18: NO), the refrigerant leak detection sensor 13 is intermittently driven (step SA19). This makes it possible in the air conditioning system 11 to suppress a decrease in the amount of power stored in the power storage unit 52 compared to driving the refrigerant leak detection sensor 13 continuously.

In this embodiment, the refrigerant leakage detection sensor 13 is driven intermittently when the time has passed to reach ½ LFL, but the present disclosure is not limited to this. That is, when a slow leak of refrigerant occurs in the indoor space 70, it is sufficient that the time has passed to enable the refrigerant leakage detection sensor 13 to detect the refrigerant.
Furthermore, in step SA19, the external power supply control unit 50 may extend the stop time of the refrigerant leakage detection sensor 13 over time. This makes it possible, in the air conditioning system 11, to shorten the time that the refrigerant leakage detection sensor 13 is operated until the commercial AC power supply 9 is restored, and to suppress a decrease in the amount of power stored in the power storage unit 52.

If the refrigerant leak detection sensor 13 detects a refrigerant leak (step SA18: YES), the external power supply control unit 50 causes each component of the air conditioning system 11 to perform steps SA14 to SA16 described above.

If it is determined in step SA9 that the refrigerant leakage detection sensor 13 is not functioning normally (step SA9: NO), the external power supply control unit 50 causes the ventilation device 14 to perform the same drive as in step SA15. That is, the ventilation device 14 performs the second ventilation operation. The external power supply control unit 50 also causes the alarm device 16 to be activated (step SA21). The alarm device 16 notifies the management center that the refrigerant leakage detection sensor 13 has detected a refrigerant.
However, the present invention is not limited to this. In step SA21, the first ventilation operation of the ventilation device 14 may be executed, similarly to step SA14.

As a result, in the air conditioning system 1, the time for which the ventilation device 14 is operated can be shortened until the refrigerant leakage location is repaired, and a decrease in the amount of power stored in the power storage unit 52 can be suppressed.
Then, the refrigerant leakage location is repaired by an operator instructed by the management center (step SA22).

[1-3. Effects, etc.]

As described above, in this embodiment, the air conditioning system 1 includes a refrigeration cycle that circulates the refrigerant, an indoor heat exchanger 29 connected to the refrigeration cycle, an indoor unit 11 installed in an indoor space 70, a refrigerant leakage detection sensor 13 that detects refrigerant leaking from the indoor unit 11, a ventilation device 14 that ventilates the indoor space, a power storage unit 52 that is charged by an external power supply kit 15, and an external power supply control unit 50. The refrigerant leakage detection sensor 13 and the ventilation device 14 are operated by a commercial AC power supply 9, and the external power supply control unit 50 operates the refrigerant leakage detection sensor 13 and the ventilation device 14 using the power of the power storage unit 52 according to the amount of power remaining in the power storage unit 52 when the supply of the commercial AC power supply 9 is stopped.

As a result, in the air conditioning system 1, when the commercial AC power supply 9 is in a power outage state, the refrigerant leakage detection sensor 13 and the ventilation device 14 are driven according to the remaining amount of power in the power storage unit 52.
Therefore, in the air conditioning system 1, even if the commercial AC power supply 9 is in a power outage state, the multiple devices for preventing refrigerant leakage can be driven for a predetermined period of time.

As in this embodiment, the external power supply control unit 50 may operate the ventilation device 14 using the power from the power storage unit 52 so that the air in the indoor volume of the indoor space 70 is ventilated when the supply of commercial AC power supply 9 is stopped.
As a result, in the air conditioning system 1, when the commercial AC power supply 9 is in a power outage state, the ventilation device 14 is driven by the amount of power stored in the power storage unit 52.
Therefore, in the air conditioning system 1, even if the commercial AC power supply 9 is in a power outage, the ventilation device 14 can be driven to diffuse the refrigerant that has leaked into the indoor space 70, effectively diluting the concentration of the refrigerant.

As in this embodiment, when the external power supply control unit 50 operates the refrigerant leak detection sensor 13 and the ventilation device 14 using power from the power storage unit 52, the external power supply control unit 50 may operate the ventilation device 14 for a predetermined time depending on the amount of power remaining in the power storage unit 52 and the ventilation volume of the ventilation device 14.

As a result, in the air conditioning system 1, the operating time of the ventilation device 14 is determined based on the concentration of refrigerant in the indoor space 70 in which the indoor unit 11 is installed, the ventilation volume of the ventilation device 14, and the remaining amount of power in the storage unit 52.
Therefore, in the air conditioning system 1, the ventilation device 14 can be operated at a ventilation volume that is sufficient to reduce the concentration of leaked refrigerant in the indoor space 70 in which the indoor unit 11 is installed, while suppressing a decrease in the amount of power stored in the power storage unit 52.

As in this embodiment, assuming that refrigerant has leaked into the indoor space 70 during a power outage, the external power supply control unit 50 may operate the ventilation device 14 for a period of time or longer until the refrigerant concentration in the indoor space 70 falls below a predetermined value.
As a result, in the air conditioning system 1, when the commercial AC power source 9 experiences a power outage and refrigerant leaks into the indoor space 70, the ventilation device 14 is driven using power from the storage unit 52 for a period of time sufficient to reduce the refrigerant concentration in the indoor space.
Therefore, in the air conditioning system 1, even if the commercial AC power supply 9 is in a power outage, the ventilation device 14 can be driven to diffuse the refrigerant that has leaked into the indoor space 70, thereby more reliably diluting the concentration of the refrigerant.

As in this embodiment, the time required for the refrigerant concentration in the indoor space 70 to become equal to or lower than a predetermined value may be equal to or shorter than the time required for the ventilation device 14 to ventilate the air in the indoor volume.
As a result, in the air conditioning system 1, if refrigerant leaks into the indoor space 70, the ventilation device 14 is operated for an operating time that is less than the time required to ventilate the entire indoor volume, which is the volume of the indoor space.
Therefore, in the air conditioning system 1, the decrease in the amount of electricity stored in the storage unit 52 is suppressed while the ventilation device 14 is driven to diffuse the refrigerant that has leaked into the indoor space 70, thereby diluting the refrigerant concentration in the indoor space 70 to below a predetermined value.

As in the present embodiment, when the supply of commercial AC power 9 is stopped, the external power supply control unit 50 may operate the refrigerant leak detection sensor 13 using the power of the power storage unit 52, and may perform a first ventilation operation to operate the ventilation device 14 using the power of the power storage unit 52 when the refrigerant leak detection sensor 13 detects a refrigerant leak and/or when it is determined that the refrigerant leak detection sensor 13 is not functioning normally.
As a result, in the air conditioning system 1, when the refrigerant leakage detection sensor 13 and the ventilation device 14 are driven by power from the power storage unit 52, the ventilation device 14 is driven according to the detection result or detection state of the refrigerant leakage detection sensor 13. Therefore, in the air conditioning system 1, the ventilation device 14 can be driven while suppressing a decrease in the amount of power stored in the power storage unit 52, thereby more reliably diffusing the refrigerant that has leaked into the indoor space 70.

As in the present embodiment, the external power supply control unit 50 may execute a second ventilation operation in which the ventilation device 14 is alternately driven and stopped repeatedly after a predetermined time has elapsed since the start of the first ventilation operation.
As a result, in the air conditioning system 1, the time that the ventilator 14 is operated per given hour can be shortened, and a decrease in the amount of power stored in the power storage unit 52 can be suppressed.
Therefore, in the air conditioning system 1, the ventilation device 14 can be driven for a long period of time.

As in this embodiment, the external power supply control unit 50 may, after a predetermined time has elapsed since executing the second ventilation operation, execute a third ventilation operation in which the ventilation device 14 is alternately driven and stopped, and the time the ventilation device 14 is stopped is longer than that of the second ventilation operation.
As a result, in the air conditioning system 1, the time that the ventilator 14 is operated per given hour can be further shortened, and a decrease in the amount of power stored in the power storage unit 52 can be suppressed.
Therefore, in the air conditioning system 1, the ventilation device 14 can be driven for a longer period of time.

As in the present embodiment, the external power supply control unit 50 may execute a fourth ventilation operation in which the ventilation volume of the ventilation device 14 is reduced after a predetermined time has elapsed since the start of the first ventilation operation.
As a result, in the air conditioning system 1, the amount of drive of the ventilator 14 per given time period can be reduced, and the consumption of the electricity stored in the power storage unit 52 can be reduced.
Therefore, in the air conditioning system 1, the ventilation device 14 can be driven for a longer period of time.

As in this embodiment, when the external power supply control unit 50 operates the refrigerant leak detection sensor 13 and the ventilation device 14 using power from the power storage unit 52, the external power supply control unit 50 may operate the ventilation device 14 while stopping the supply of power to the refrigerant leak detection sensor 13.
This prevents the refrigerant leakage detection sensor 13 and the ventilation device 14 from being driven at the same time.
Therefore, in the air conditioning system 1, a decrease in the amount of power stored in the power storage unit 52 can be suppressed.

As in this embodiment, when the external power supply control unit 50 operates the refrigerant leak detection sensor 13 and the ventilation device 14 using power from the power storage unit 52, the external power supply control unit 50 may operate the refrigerant leak detection sensor 13 a predetermined time after the ventilation device 14 is stopped.
As a result, if a refrigerant leak occurs, the refrigerant leak detection sensor 13 detects the refrigerant leak while a predetermined amount of the refrigerant is retained. Therefore, in the air conditioning system 1, it is possible to suppress detection failures by the refrigerant leak detection sensor 13, shorten the drive time of the refrigerant leak detection sensor 13, and suppress a decrease in the amount of power stored in the power storage unit 52.

As in this embodiment, when the supply of commercial AC power 9 is stopped, the external power supply control unit 50 may intermittently operate the refrigerant leakage detection sensor 13 after either the ventilation device 14 is stopped or the refrigerant leakage detection sensor 13 starts operating, and a time has elapsed until the refrigerant reaches a predetermined concentration.
As a result, in the air conditioning system 1, the time that the refrigerant leakage detection sensor 13 is driven per given time period can be shortened, and a decrease in the amount of power stored in the power storage unit 52 can be suppressed.
Therefore, in the air conditioning system 1, the refrigerant leakage detection sensor 13 can be driven for a longer period of time.

(Embodiment 2)
The second embodiment will be described below with reference to FIG.
FIG. 5 is a block diagram showing the configuration of an air conditioning system 1 according to the second embodiment.
In FIG. 5, the same parts as those in FIG. 1 are denoted by the same reference numerals and the description thereof will be omitted.
[2-1. Configuration]
The air conditioning system 100 according to the second embodiment differs from the air conditioning system 1 according to the first embodiment at least in that a heat source detection sensor 80 is provided. This heat source detection sensor 80 is an example of a device that detects whether or not there is a person or something that may be affected by leaking refrigerant in the indoor space 70 in which the indoor unit 11 of the air conditioning system 100 is provided.
[2-1-2. Configuration of heat source sensor]

In the present embodiment, the heat source detection sensor 80 is provided in the indoor space 70. The heat source detection sensor 80 may be provided integrally with the indoor unit 11.
The heat source sensor 80 is a thermal sensor, such as an infrared detector or a thermistor, that detects a heat source that generates a temperature above a predetermined level in an indoor space. The heat source sensor 80 of this embodiment detects a heat source that has a temperature above a level that may be an ignition source for the refrigerant used in the air conditioning system 1. Such a heat source is, for example, a lighter flame or an electric heater.
In the air conditioning system 100, the heat source may be detected not only by a heat sensor but also by a camera or the like.

This heat source sensor 80 is configured to be able to communicate with both the indoor unit control unit 20 and the external power supply control unit 50. Both the indoor unit control unit 20 and the external power supply control unit 50 can obtain the detection results of the heat source sensor 80.

[2-2. Operation]
The operation of the air conditioning system 100 configured as above will be described below.
FIG. 6 is a flowchart showing the operation of the air conditioning system 100 when the commercial AC power supply 9 is in a power outage state.
As described above, in the air conditioning system 100, when the commercial AC power supply 9 is in a power outage state, the external power supply control unit 50 detects that the power supply from the PCB 22 to the external power supply kit 15 has stopped. Then, the external power supply control unit 50 drives the refrigerant leakage detection sensor 13 and determines whether the refrigerant leakage detection sensor 13 has detected a refrigerant leak (step SB1).

When it is determined that the refrigerant leakage detection sensor 13 has detected a refrigerant leakage (step SB1: YES), the external power supply control unit 50 drives the ventilation device 14, stops the driving of the refrigerant leakage detection sensor 13, and drives the alarm device 16 (step SB2). The alarm device 16 notifies the management center that the refrigerant leakage detection sensor 13 has detected a refrigerant.
Furthermore, by preventing the refrigerant leakage detection sensor 13 and the ventilation device 14 from being driven simultaneously, a decrease in the amount of electric power stored in the power storage unit 52 is prevented.

Then, the refrigerant leak is repaired by a worker instructed by the management center (step SB3).

In step SB1, if it is determined that the refrigerant leak detection sensor 13 has not detected a refrigerant leak (step SB1: NO), the external power supply control unit 50 drives the heat source detection sensor 80 and detects, from the detection result of the heat source detection sensor 80, whether or not there is a heat source whose temperature is equal to or higher than that which could be a source of ignition of the refrigerant (step SB4).
When the external power supply control unit 50 determines that the heat source is present (step SB4: YES), it drives the ventilation device 14 and stops driving the refrigerant leakage detection sensor 13 (step SB5).

Then, the external power supply control unit 50 operates the ventilation device 14 for a predetermined time and then stops it (step SB6). Here, this predetermined time is a ventilation time determined by the external power supply control unit 50 in accordance with the remaining amount of power in the power storage unit 52, between the set time T1, which is the upper limit value described in the first embodiment, and the set time T2, which is the lower limit value.

After the ventilation device 14 is stopped, the external power supply control unit 50 drives the refrigerant leakage detection sensor 13 and determines whether the refrigerant leakage detection sensor 13 has detected a refrigerant leakage (step SB7).
If the refrigerant leakage detection sensor 13 detects a refrigerant leakage (step SB7: YES), the external power supply control unit 50 causes each unit of the air conditioning system 100 to carry out steps SB2 and SB3.

If it is determined in step SB7 that the refrigerant leak detection sensor 13 has not detected a refrigerant leak (step SB7: NO), the external power supply control unit 50 stops driving the refrigerant leak detection sensor 13 (step SB8). Then, it is determined whether the commercial AC power supply 9 has recovered from a power outage (step SB9). If it is determined that the commercial AC power supply 9 has recovered from a power outage, the external power supply control unit 50 returns the air conditioning system 100 to normal operation (step SB10).

If it is determined in step SB4 that a heat source is present in the indoor space 70 (step SB11: NO), the external power supply control unit 50 continues to stop the ventilation device 14 and activates the refrigerant leakage detection sensor 13 (step SB11). Then, step SB7 is performed to determine whether the refrigerant leakage detection sensor 13 has detected a refrigerant leak.

In the second embodiment, the heat source sensor 80 is used to control the air conditioning system 100 depending on the presence or absence of a heat source in the indoor space 70. However, this is not limiting, and for example, a camera, an objective sensor, a human sensor, etc. may be used to detect the presence or absence or number of people in the indoor space 70, and the air conditioning system 100 may be controlled based on the detection results. Furthermore, when making these judgments, a predetermined volume Vr in the indoor space 70 or the volume of the entire indoor space 70, etc. may be reflected.

Other Embodiments
As described above, the first and second embodiments have been described as examples of the technology disclosed in this application. However, the technology in this disclosure is not limited to these, and can be applied to embodiments in which modifications, substitutions, additions, omissions, etc. are made. In addition, it is also possible to combine the components described in the first and second embodiments to create new embodiments.
Therefore, other embodiments will be exemplified below.

In the above-described embodiment, the number of outdoor units 3 and indoor units 11 included in the air conditioning system 1, 100 is not limited. For example, the air conditioning system 1 may be configured with one outdoor unit 3 and one indoor unit 11 connected together.

In the above-described embodiment, in the configurations of Figs. 1 and 5, the devices that are supplied with commercial power are configured to receive power from a common commercial AC power source 9, but this is not limited thereto, and a commercial AC power source 9 may be provided independently for some or all of the devices. In other words, multiple commercial AC power sources 9 may be connected to the air conditioning system 1, 100.

The refrigerant leak detection sensor 13 may be disposed inside the housing of the indoor unit 11. In this case, the refrigerant leak detection sensor 13 may be driven immediately after the ventilation device 14 is stopped in step SA12 described above. In this case, step SA17 may be omitted.

The above-described embodiments are intended to illustrate the technology disclosed herein, and various modifications, substitutions, additions, omissions, etc. may be made within the scope of the claims or their equivalents.

This disclosure is applicable to air conditioning systems that have devices for preventing multiple refrigerant leaks. Specifically, this disclosure is applicable to air conditioning systems that operate devices for preventing multiple refrigerant leaks even during a power outage.

1, 100 Air conditioning unit 9 Commercial AC power supply (commercial power supply)
11 Indoor unit 13 Refrigerant leakage detection sensor (detection sensor)
14 Ventilation device 15 External power supply kit 29 Indoor heat exchanger (heat exchanger)
48 Heat source sensor 50 External power supply control unit 52 Power storage unit 70 Indoor space

Claims (12)

A refrigeration cycle that circulates a slightly flammable refrigerant or a flammable refrigerant;
an indoor unit provided with a heat exchanger connected to the refrigeration cycle and installed in an indoor space;
A refrigerant sensor that detects refrigerant leaking from the indoor unit;
A ventilation device for ventilating the indoor space;
a power storage unit that is charged by a commercial power source;
A control unit.
The refrigerant sensor and the ventilation device are operated by a commercial power source,
The control unit operates the ventilator using power from the power storage unit when the supply of the commercial power source is stopped,
After operating the ventilation device, determining whether the refrigerant sensor is functioning normally;
When it is determined that the refrigerant sensor is functioning normally, the operation of the ventilation device is continued for a predetermined time.
An air conditioning system characterized by: The air conditioning system according to claim 1 , wherein the control unit operates the ventilation device using the power of the power storage unit so that air in a room volume is ventilated when the supply of the commercial power source is stopped. The air conditioning system according to claim 1 or 2, wherein the control unit operates the ventilation device for a predetermined time period depending on an amount of power remaining in the power storage unit and a ventilation volume of the ventilation device. The air conditioning system according to any one of claims 1 to 3, characterized in that, assuming that refrigerant has leaked into the indoor space during a power outage, the control unit operates the ventilation device for a period of time or longer until a refrigerant concentration in the indoor space becomes equal to or lower than a predetermined value. The air conditioning system according to claim 4, wherein the time during which the refrigerant concentration in the indoor space becomes equal to or lower than the predetermined value is equal to or shorter than the time required for the ventilation device to ventilate the air in the indoor volume. The control unit operates the refrigerant sensor using electric power from the power storage unit when the supply of the commercial power source is stopped,
6. The air conditioning system according to claim 1, further comprising: a first ventilation operation for operating the ventilation device using power from the power storage unit when the refrigerant sensor detects a refrigerant leak and/or when it is determined that the refrigerant sensor is not functioning normally. The air conditioning system according to claim 6, wherein the control unit executes a second ventilation operation in which the ventilation device is alternately driven and stopped, after a predetermined time has elapsed since the start of the first ventilation operation. The air conditioning system according to claim 7, characterized in that, after a predetermined time has elapsed since the second ventilation operation was performed, the control unit performs a third ventilation operation in which the ventilation device is alternately driven and stopped, and the ventilation device is stopped for a longer period of time than in the second ventilation operation. The air conditioning system according to any one of claims 6 to 8, characterized in that the control unit executes a fourth ventilation operation to reduce a ventilation volume of the ventilation device after a predetermined time has elapsed since starting the first ventilation operation. The air conditioning system according to any one of claims 1 to 9, characterized in that, when the control unit operates the refrigerant sensor and the ventilation device using power from the power storage unit, the control unit operates the ventilation device in a state in which power supply to the refrigerant sensor is stopped. The air conditioning system according to any one of claims 1 to 10, characterized in that, when the control unit operates the refrigerant sensor and the ventilation device using power from the storage unit, the control unit operates the refrigerant sensor after a predetermined time has elapsed since the ventilation device was stopped. When the supply of the commercial power source is stopped, the control unit
The air conditioning system according to any one of claims 1 to 11, characterized in that, after either one of stopping the ventilation device and starting the operation of the refrigerant sensor, when a time has elapsed until the refrigerant reaches a predetermined concentration, the refrigerant sensor is operated intermittently.

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