JP7481636B2 - Ultraviolet irradiation unit and air conditioning device - Google Patents

Description

This disclosure relates to an ultraviolet irradiation unit and an air conditioning device.

Conventionally, air conditioners equipped with an ultraviolet irradiation unit (irradiation section) that irradiates ultraviolet rays are known (see, for example, Patent Document 1). The air conditioner is equipped with an air conditioning control section that controls various operations of the air conditioner, and the operation of the ultraviolet irradiation unit is controlled by the air conditioning control section.

JP 2021-055892 A

In the air conditioning device, the ultraviolet irradiation unit may be an optional item. In other words, the air conditioning device may be used in a configuration that does not include an ultraviolet irradiation unit. However, in the air conditioning device, regardless of whether or not an ultraviolet irradiation unit is included, it is necessary to store a control program for controlling the ultraviolet irradiation unit in advance in the air conditioning control unit.

The present disclosure aims to provide an ultraviolet irradiation unit that does not require a control program for the unit to be stored in the air conditioning control unit of an air conditioner, and an air conditioner equipped with the same.

(1) The ultraviolet irradiation unit disclosed herein is an ultraviolet irradiation unit that can be attached to an air conditioning apparatus that includes an indoor unit having an indoor fan and an air conditioning control unit that controls the operation of the indoor unit, and includes a light source that irradiates ultraviolet light to the indoor unit, and a light source control unit that is capable of communicating with the air conditioning control unit and controls the operation of the light source, and when the light source control unit receives a first signal transmitted from the air conditioning control unit, the light source is powered on.

The ultraviolet irradiation unit of the present disclosure eliminates the need to previously store a control program for controlling the ultraviolet irradiation unit in the air conditioning control unit of an air conditioner to which the ultraviolet irradiation unit can be attached. Therefore, by using the ultraviolet irradiation unit of the present disclosure, the configuration of the air conditioning control unit can be simplified.

(2) In the ultraviolet irradiation unit disclosed herein, it is preferable that the light source control unit turns off the power supply to the light source when a predetermined period of time has elapsed after receiving the first signal.

In this case, the light source control unit can easily turn the light source on and off. This simplifies the configuration of the light source control unit of the ultraviolet irradiation unit.

(3) In the ultraviolet irradiation unit disclosed herein, it is preferable that the light source control unit turns off the power supply to the light source when the light source control unit receives a second signal transmitted from the air conditioning control unit when the air conditioning device stops operating or when the indoor fan stops operating.

In this case, the light source control unit can easily turn the light source on and off depending on the operating state of the air conditioning device.

(4) The air conditioning apparatus of the present disclosure includes an indoor unit having a casing with an inlet for drawing in indoor air, an indoor fan housed in the casing, and a collection member housed in the casing; an air conditioning control unit that controls the operation of the indoor unit; an ultraviolet irradiation unit having a light source that irradiates the collection member with ultraviolet light; and a light source control unit that is capable of communicating with the air conditioning control unit and controls the operation of the light source, and when the light source control unit receives a first signal transmitted from the air conditioning control unit, it turns on the power of the light source.

According to the air conditioning device of the present disclosure, it is not necessary to store a control program for controlling the ultraviolet irradiation unit in advance in the air conditioning control unit. Therefore, in the air conditioning device of the present disclosure, it is possible to simplify the configuration of the air conditioning control unit.

(5) In the air conditioning device of the present disclosure, it is preferable that the air conditioning control unit transmits the first signal when operation of the air conditioning device is started or when operation of the indoor fan is started.

In this case, the configuration of the air conditioning control unit can be simplified.

(6) In the air conditioning device of the present disclosure, it is preferable that the light source control unit turns off the power supply to the light source after a predetermined period of time has elapsed after receiving the first signal.

In this case, the light source control unit can easily turn the light source on and off depending on the operating state of the air conditioning device.

(7) In the air conditioning device disclosed herein, it is preferable that when the air conditioning device stops operating or when the indoor fan stops operating, the air conditioning control unit transmits a second signal, and when the light source control unit receives the second signal, the light source is powered off.

In this case, the configuration of the light source control unit can be simplified.

(8) The air conditioning apparatus of the present disclosure preferably further includes an alarm unit, and when the light source control unit detects an abnormality in the light source, the light source control unit transmits a third signal to the air conditioning control unit, and when the air conditioning control unit receives the third signal, the alarm unit issues an alarm.

In this case, the notification unit can notify the user that an abnormality has occurred in the light source.

(9) In the air conditioning device disclosed herein, the light source control unit receives first information regarding the indoor temperature from the air conditioning control unit, and the light source control unit turns the power of the light source on and off based on the first information.

In this case, a simple light source control unit can suppress deterioration of the light source due to the influence of the surrounding temperature.

1 is a schematic configuration diagram of an air conditioning apparatus equipped with an ultraviolet irradiation unit according to the present disclosure. FIG. 2 is a control block diagram of the air conditioning apparatus of the present disclosure. FIG. 2 is a perspective view showing an indoor unit of the air conditioner according to the present disclosure. FIG. 4 is a cross-sectional view showing the indoor unit with the decorative panel removed. FIG. 4 is a perspective view showing the indoor unit with the decorative panel and protective member removed. FIG. 4 is a partially enlarged perspective view showing the ultraviolet irradiation unit attached to the air conditioning apparatus. FIG. FIG. 4 is a control flow diagram of a light source control unit according to the first embodiment. FIG. 11 is a control flow diagram of a light source control unit according to the second embodiment. FIG. 13 is a control flow diagram of a light source control unit according to the third embodiment. FIG. 13 is a control flow diagram of a light source control unit according to the fourth embodiment.

Below, we will explain in detail an embodiment of the ultraviolet irradiation unit and an air conditioning device equipped with the same disclosed herein, with reference to the attached drawings.

(Overview of air conditioning equipment)
FIG. 1 is a schematic diagram of an air conditioner equipped with an ultraviolet irradiation unit of the present disclosure. The air conditioner 10 shown in FIG. 1 is an embodiment of the air conditioner of the present disclosure, and can perform cooling and heating of a target space constructed inside a building by performing a vapor compression refrigeration cycle, and adjusts the temperature of the air in the target space to a predetermined target temperature. The air conditioner 10 includes an indoor unit 20 and an outdoor unit 30. In this embodiment, the air conditioner 10 is illustrated as having a configuration in which one indoor unit 20 is connected to one outdoor unit 30. However, the number of indoor units 20 and outdoor units 30 is not limited to this. In this embodiment, the air conditioner 10 is illustrated as an example of an air conditioner that performs cooling and heating by circulating a refrigerant in a refrigerant circuit, but the air conditioner of the present disclosure is not limited to this, and may be an air conditioner that performs cooling and heating by circulating cold water and hot water supplied from a heat source device, and the indoor unit may be a so-called fan coil unit.

The indoor unit 20 includes a casing 21, an indoor fan 22, an indoor heat exchanger 23, and a collection member 24.

The casing 21 has an intake port 25 and an air supply port 26. The indoor fan 22 is configured to take in indoor air (return air RA) from the intake port 25 into the inside of the casing 21, exchange heat between the taken-in air and the refrigerant in the indoor heat exchanger 23, and then blow the air (supply air SA) into the room from the air supply port 26. The indoor fan 22 has a motor (not shown) whose operating speed can be adjusted, for example, by inverter control. The indoor heat exchanger 23 constitutes part of the refrigerant circuit 40, which will be described later. The indoor heat exchanger 23 is a cross-fin tube type or microchannel type heat exchanger, and is used to exchange heat with the indoor air.

The indoor unit 20 is provided with a collection member 24 inside the casing 21. The collection member 24 is a member for collecting dust contained in the air in the indoor space (return air RA), and is disposed inside the casing 21 near the intake port 25. In the air conditioning device 10, the entire amount of air taken into the casing 21 from the intake port 25 passes through the collection member 24.

The air conditioning device 10 of the present disclosure further includes an ultraviolet irradiation unit 50. The ultraviolet irradiation unit 50 is disposed inside the casing 21 of the indoor unit 20. The ultraviolet irradiation unit 50 is a unit for irradiating the collection member 24 with ultraviolet rays UV, and includes a light source 51. The light source 51 includes an LED element that emits ultraviolet rays UV when electricity is applied. A lens (not shown) is attached to the light source 51, and the lens diffuses the ultraviolet rays UV emitted by the light source 51 and irradiates them on the collection member 24, which is part of the indoor unit 20.

The outdoor unit 30 includes a casing 31, an outdoor fan 32, an outdoor heat exchanger 33, a compressor 34, a four-way switching valve 35, an electric expansion valve 36, a liquid stop valve 37, and a gas stop valve 38. The compressor 34, the four-way switching valve 35, the outdoor heat exchanger 33, the electric expansion valve 36, the liquid stop valve 37, and the gas stop valve 38 form part of the refrigerant circuit 40, which will be described later.

The air conditioner 10 has a communication pipe 27. The communication pipe 27 circulates refrigerant between the indoor unit 20 and the outdoor unit 30. The air conditioner 10 has a refrigerant circuit 40 including a compressor 34, a four-way switching valve 35, an outdoor heat exchanger 33, an electric expansion valve 36, a liquid shutoff valve 37, an indoor heat exchanger 23, a gas shutoff valve 38, and refrigerant piping connecting these. The refrigerant circuit 40 includes a gas refrigerant pipe 40G and a liquid refrigerant pipe 40L.

The outdoor fan 32 is equipped with a motor (not shown) whose operating speed can be adjusted by inverter control. The outdoor fan 32 is configured to take in outdoor air into the inside of the casing 31, perform heat exchange between the taken-in air and the refrigerant in the outdoor heat exchanger 33, and then blow the air out of the casing 31.

The outdoor heat exchanger 33 is, for example, a cross-fin tube type or a microchannel type heat exchanger, and is used to exchange heat with the refrigerant using air as a heat source.

The compressor 34 draws in low-pressure gas refrigerant and discharges high-pressure gas refrigerant. The compressor 34 is equipped with a motor (not shown) whose operating speed can be adjusted by inverter control. The compressor 34 is a variable capacity type (variable capacity type) whose capacity (capacity) can be changed by inverter control of the motor. Note that, although the present embodiment illustrates an air conditioning apparatus 10 equipped with one compressor 34 in the outdoor unit 30, the configuration of the air conditioning apparatus of the present disclosure is not limited to this configuration.

The four-way switching valve 35 reverses the flow of refrigerant in the refrigerant piping, switching the refrigerant discharged from the compressor 34 to either the outdoor heat exchanger 33 or the indoor heat exchanger 23. This allows the air conditioning device 10 to switch between cooling and heating operation. The motorized expansion valve 36 is composed of an electric valve that can adjust the refrigerant flow rate, etc.

The liquid shutoff valve 37 and the gas shutoff valve 38 are manually operated on-off valves. When closed, the liquid shutoff valve 37 and the gas shutoff valve 38 block the flow of refrigerant in the gas refrigerant pipe 40G and the liquid refrigerant pipe 40L, and when open, allow the flow of refrigerant in the gas refrigerant pipe 40G and the liquid refrigerant pipe 40L.

The indoor unit 20 is equipped with an indoor temperature sensor 41 that detects the temperature of the return air RA. The indoor temperature sensor 41 is connected to the air conditioning control unit 15, which will be described later. The outdoor unit 30 is equipped with a refrigerant temperature sensor, an outdoor air temperature sensor, etc., not shown. In the air conditioning device 10, the evaporation pressure, condensation pressure, degree of superheat, etc. of the indoor heat exchanger 23 and the outdoor heat exchanger 33 are calculated using the detection values of each of these sensors, and the rotation speed of the compressor 34 and the opening degree of the electric expansion valve 36 are controlled to adjust these values.

When the air conditioner 10 having the above configuration performs cooling operation, the four-way switching valve 35 is held in the state shown by the solid line in FIG. 1. The high-temperature, high-pressure gaseous refrigerant discharged from the compressor 34 flows into the outdoor heat exchanger 33 through the four-way switching valve 35, and is condensed and liquefied by heat exchange with the outdoor air due to the operation of the outdoor fan 32. When the air conditioner 10 performs cooling operation, the outdoor heat exchanger 33 functions as a condenser. The liquefied refrigerant passes through the fully open electric expansion valve 36 and flows into the indoor unit 20. In the indoor unit 20, the refrigerant exchanges heat with the indoor air in the indoor heat exchanger 23 and evaporates. The indoor air cooled by the evaporation of the refrigerant is blown into the room by the indoor fan 22 to cool the room. The refrigerant evaporated in the indoor heat exchanger 23 returns to the outdoor unit 30 through the gas refrigerant piping 40G, and is sucked into the compressor 34 through the four-way switching valve 35. When the air conditioning device 10 is in cooling operation, the indoor heat exchanger 23 functions as an evaporator.

When the air conditioning device 10 performs heating operation, the four-way switching valve 35 is held in the state shown by the broken line in FIG. 1. The high-temperature, high-pressure gaseous refrigerant discharged from the compressor 34 passes through the four-way switching valve 35 and flows into the indoor heat exchanger 23 of the indoor unit 20. In the indoor heat exchanger 23, the refrigerant exchanges heat with the indoor air and condenses and liquefies. When the air conditioning device 10 performs heating operation, the indoor heat exchanger 23 functions as a condenser. The indoor air heated by the condensation of the refrigerant is blown into the room by the indoor fan 22, heating the room. The refrigerant liquefied in the indoor heat exchanger 23 returns to the outdoor unit 30 through the liquid refrigerant piping 40L, is decompressed to a predetermined low pressure by the electric expansion valve 36, and is further evaporated by heat exchange with the outdoor air in the outdoor heat exchanger 33. The refrigerant evaporated and vaporized in the outdoor heat exchanger 33 is sucked into the compressor 34 through the four-way switching valve 35. When the air conditioning device 10 is in heating operation, the outdoor heat exchanger 33 functions as an evaporator.

[Regarding the control unit]
Fig. 2 is a control block diagram of the air conditioner of the present disclosure. As shown in Fig. 2, the air conditioner 10 is equipped with an air conditioning control unit 15 that controls the operation of the air conditioner 10. The air conditioning control unit 15 includes an indoor control unit (not shown) arranged in the indoor unit 20 and an outdoor control unit (not shown) arranged in the outdoor unit 30. The indoor control unit and the outdoor control unit are connected to each other so that they can communicate with each other via a transmission line. A remote control 16 is connected to the air conditioning control unit 15, which allows a user to operate and stop the indoor unit 20, change the set temperature, etc.

The air conditioning control unit 15 is a device that controls the operation of the indoor unit 20 and the outdoor unit 30, and is configured, for example, by a microcomputer equipped with a processor such as a CPU, and memories such as RAM and ROM. The air conditioning control unit 15 may be realized as hardware using an LSI, an ASIC, an FPGA, or the like. The air conditioning control unit 15 performs a predetermined function by having the processor execute a program installed in the memory. The detection values of each sensor provided in the indoor unit 20 and the outdoor unit 30 are input to the air conditioning control unit 15. The air conditioning control unit 15 controls the operation of the indoor fan 22, the outdoor fan 32, the compressor 34, the four-way switching valve 35, the motorized expansion valve 36, etc. based on the detection values of each sensor, etc.

The air conditioning control unit 15 transmits a first signal S1 and a second signal S2. The first signal S1 is a signal that permits the operation of an optional item attached to the air conditioning unit 10, and the second signal S2 is a signal that stops the optional item. In the air conditioning unit 10, the first signal S1 and the second signal S2 transmitted by the air conditioning control unit 15 are input to the light source control unit 52, which will be described later.

It is preferable that the air conditioning control unit 15 transmits the first information J1 to the light source control unit 52, which will be described later. The first information J1 is information relating to the indoor temperature detected by the indoor temperature sensor 41. In the air conditioning device 10, the first information J1 transmitted by the air conditioning control unit 15 is input to the light source control unit 52. The light source control unit 52 can grasp the temperature around the light source 51 based on the first information J1. Note that the air conditioning device 10 of the present disclosure does not need to transmit the first information J1 from the air conditioning control unit 15 to the light source control unit 52.

The remote control 16 is an operation unit that allows the user to operate the air conditioning device 10, such as starting and stopping the device and changing settings. In the air conditioning device 10 of the present disclosure, the remote control 16 is provided with a display unit 17. The display unit 17 is a part that can display the operating state and setting values of the air conditioning device 10. In the air conditioning device 10, the user can understand the operating state of the air conditioning device 10 based on the information presented on the display unit 17.

In the air conditioning device 10, the ultraviolet irradiation unit 50 is connected to the air conditioning control unit 15. The ultraviolet irradiation unit 50 is equipped with a light source control unit 52 that controls the operation of the ultraviolet irradiation unit 50. The light source control unit 52 is a device that controls the operation of the light source 51 (turning the power of the light source 51 ON and OFF), and is composed of, for example, a microcomputer equipped with a processor such as a CPU and memories such as a RAM and a ROM. The light source control unit 52 may be realized as hardware using an LSI, an ASIC, an FPGA, etc. The light source control unit 52 exerts a predetermined function by the processor executing a program installed in the memory. The light source control unit 52 is capable of detecting an abnormality in the light source 51. When the light source control unit 52 detects an abnormality in the light source 51, it transmits a third signal S3. The third signal S3 is a signal indicating that an abnormality has occurred in the light source 51. In the air conditioning device 10, the third signal S3 transmitted by the light source control unit 52 is input to the air conditioning control unit 15.

(Configuration of indoor unit)
Fig. 3 is a perspective view showing an indoor unit of the air conditioning apparatus of the present disclosure. Fig. 4 is a cross-sectional view showing the indoor unit with the decorative panel removed. Fig. 5 is a perspective view showing the indoor unit with the decorative panel and protective member removed. As shown in Figs. 3 to 5, the indoor unit 20 has a so-called cassette type configuration, and includes a casing 21 and a decorative panel 28.

The casing 21 has a substantially rectangular shape in bottom view, and includes a first casing 21a arranged on the upper side and a second casing 21b arranged on the lower side. As shown in FIG. 4, a space A is formed inside the casing 21 to accommodate the indoor fan 22, the indoor heat exchanger 23, the collection member 24, the ultraviolet irradiation unit 50, etc. The space A also serves as an air flow path inside the casing 21. As shown in FIG. 4, an intake port 25 is formed in the rectangular central portion of the lower end of the casing 21, and four air supply ports 26 are formed surrounding the intake port 25. The intake port 25 and the air supply port 26 are openings formed at the lower end of the space A. A protective member 70 is disposed at the lower end of the intake port 25. The protective member 70 is a member for preventing the intrusion of fingers into the intake port 25. In the indoor unit 20 in a normal use state, the lower end of the second casing 21b is covered with a decorative panel 28 (see FIG. 3).

As shown in FIG. 3, the decorative panel 28 has a substantially rectangular shape when viewed from the bottom, and an intake grille 29 is disposed in the center of the rectangle. The decorative panel 28 has four air outlets 28a disposed around the intake grille 29. The intake grille 29 has a slit-shaped opening 29a. The opening 29a is connected to the space A (see FIG. 4) via the intake port 25 (see FIG. 4). The air outlet 28a of the decorative panel 28 is connected to the space A (see FIG. 5) via the air supply port 26 (see FIG. 3). The indoor unit 20 draws indoor air into the casing 21 through the intake port 25 (opening 29a) and supplies the air drawn into the casing 21 into the room through the air supply port 26 and the air outlet 28a.

As shown in FIG. 4, the indoor unit 20 is equipped with an indoor fan 22 and an indoor heat exchanger 23 inside the casing 21 (space A). The indoor fan 22 is a fan for circulating air in the room. The indoor heat exchanger 23 constitutes part of the refrigerant circuit 40, and refrigerant is circulated between the indoor unit 20 and the outdoor unit 30 via a connecting pipe 27. In the indoor unit 20, by driving the indoor fan 22, indoor air (return air RA) is sucked into the casing 21 from the suction port 25 (opening 29a) and passes through the indoor heat exchanger 23, and the cooled or heated air (supply air SA) is supplied to the room from the supply port 26 and the outlet 28a.

(Collection member)
FIG. 6 is a partially enlarged perspective view showing the ultraviolet irradiation unit attached to the air conditioning device. As shown in FIGS. 4 to 6, the indoor unit 20 is provided with a collection member 24 inside the casing 21. The collection member 24 is a member for collecting dust contained in the indoor air (return air RA). The collection member 24 includes a first filter 24a which is the first collection member 24, and a second filter 24b which is the second collection member 24. The second filter 24b is a filter for collecting (finer) dust that cannot be collected by the first filter 24a, and has a finer mesh than the first filter 24a and a higher collection efficiency (about 60 to 95%). In other words, the first filter 24a has a coarser mesh than the second filter 24b. In this embodiment, the case where all the members constituting the collection member 24 are filters is illustrated, but it may be an electric dust collector.

As shown in FIG. 5, the first filter 24a is disposed upstream of the second filter 24b in the air flow direction. In the following description, the upstream surface of the first filter 24a in the air flow direction is referred to as the lower end surface 24c. Note that, although the collection member 24 shown in this embodiment includes the first filter 24a and the second filter 24b, the collection member in the indoor unit of the present disclosure may be only one of the first filter and the second filter.

In the indoor unit 20, air (return air RA) sucked into the casing 21 from the intake port 25 (opening 29a) passes through the collection member 24. At this time, dust contained in the return air RA is collected by the first filter 24a and the second filter 24b. In the indoor unit 20, dust that is the source of harmful and odorous components adheres to the lower end surface 24c of the first filter 24a.

(Ultraviolet irradiation unit)
As shown in FIG. 6, the indoor unit 20 includes an ultraviolet irradiation unit 50. The ultraviolet irradiation unit 50 is a portion for irradiating the lower end surface 24c of the first filter 24a with ultraviolet rays UV, and includes a light source 51, a light source control unit 52 (see FIG. 2), and a cover 53. The light source 51 includes an LED element that emits ultraviolet rays UV when energized. A lens (not shown) is attached to the light source 51, and the lens diffuses the ultraviolet rays UV emitted by the light source 51 over substantially the entire surface of the lower end surface 24c. The light source 51 shown in this embodiment is fixed to the casing 21 and irradiates the lower end surface 24c with ultraviolet rays UV from a fixed position, but may further include a displacement mechanism that displaces the light source 51 relative to the casing 21, and may be configured to irradiate the lower end surface 24c with ultraviolet rays UV while displacing the light source 51 by the displacement mechanism.

The ultraviolet irradiation unit 50 is disposed at a position outside the air flow from the suction port 25 toward the collection member 24. In other words, the ultraviolet irradiation unit 50 is disposed at a position that does not overlap with the suction port 25 and the collection member 24 when viewed from the bottom. If the ultraviolet irradiation unit 50 were disposed in the air flow from the suction port 25 toward the collection member 24, the ultraviolet irradiation unit 50 would be a factor in increasing ventilation resistance. In the indoor unit 20 of the present disclosure, the ultraviolet irradiation unit 50 is disposed at a position outside the air flow from the suction port 25 toward the collection member 24, thereby suppressing an increase in ventilation resistance.

The ultraviolet irradiation unit 50 includes a cover 53. The cover 53 also serves as a member for supporting the light source 51 relative to the casing 21, and is screwed to the casing 21. The cover 53 includes a main body 53a and an opening 53b. The ultraviolet rays UV emitted from the light source 51 are irradiated through the opening 53b into the space A outside the cover 53. The ultraviolet rays UV irradiated through the opening 53b into the space A outside the cover 53 are irradiated onto the lower end surface 24c of the collection member 24.

(Regarding the Notification Department)
As shown in Fig. 2, the air conditioning device 10 further includes a notification unit 60. In the air conditioning device 10, when the light source control unit 52 detects an abnormality in the light source 51, it transmits a third signal S3 to the air conditioning control unit 15. In the air conditioning device 10, when the air conditioning control unit 15 receives the third signal S3, the air conditioning control unit 15 causes the notification unit 60 to notify. In the air conditioning device 10 configured in this way, the notification unit 60 can notify the user that an abnormality has occurred in the light source 51. Note that in the air conditioning device 10, when the light source control unit 52 detects an abnormality in the light source 51, information for notifying the abnormality may be displayed on the display unit 17 of the remote control 16, for example.

[Control contents performed by the air conditioning control unit]
7 is a control flow diagram of the air conditioning control unit. When a user operates the remote control 16 (see FIG. 3) and the operation of the air conditioning apparatus 10 is turned on, the air conditioning control unit 15 (see FIG. 3) starts the control operation shown in FIG. 7. The control operation shown in FIG. 7 is an operation for controlling the operation of an optional item that can be attached to the air conditioning apparatus 10. In the present disclosure, a case where the optional item that can be attached to the air conditioning apparatus 10 is an ultraviolet irradiation unit 50 will be described as an example. Note that optional items other than the ultraviolet irradiation unit 50 include an electric dust collector, a deodorizing unit, and a discharge unit that generates active species.

As shown in FIG. 7, when the control operation for the ultraviolet irradiation unit 50 is started, the air conditioning control unit 15 executes step (S101). In step (S101), the air conditioning control unit 15 executes a determination as to whether or not the ultraviolet irradiation unit 50 is connected to the air conditioning device 10 (air conditioning control unit 15). In step (S101), if the air conditioning control unit 15 determines that the ultraviolet irradiation unit 50 is connected to the air conditioning device 10 (air conditioning control unit 15) (YES), then it executes step (S102). On the other hand, in step (S101), if the air conditioning control unit 15 determines that the ultraviolet irradiation unit 50 is not connected to the air conditioning device 10 (air conditioning control unit 15) (NO), it determines that it is not necessary to execute the control operation for the ultraviolet irradiation unit 50 and ends the control.

In step (S102), the air conditioning control unit 15 executes a determination as to whether or not there is an abnormality in the indoor unit 20. If the air conditioning control unit 15 determines in step (S102) that there is no abnormality in the indoor unit 20 (YES), it then executes step (S103). On the other hand, if the air conditioning control unit 15 determines in step (S102) that there is an abnormality in the indoor unit 20 (NO), it determines that it is not possible to execute the control operation of the ultraviolet irradiation unit 50, and ends control.

In step (S103), the air conditioning control unit 15 executes a determination as to whether or not the indoor fan 22 is ON. If the air conditioning control unit 15 determines in step (S103) that the indoor fan 22 is ON (YES), the air conditioning control unit 15 then executes step (S104). On the other hand, if the air conditioning control unit 15 determines in step (S103) that the indoor fan 22 is not ON (NO), the air conditioning control unit 15 repeatedly executes the determination in step (S103) until the indoor fan 22 is ON.

In step (S104), the air conditioning control unit 15 transmits the first signal S1. The first signal S1 is a signal that permits the operation of an optional item attached to the air conditioning device 10, and is a general-purpose signal that corresponds to all optional items that can be attached. In other words, in the air conditioning device 10 of the present disclosure, the air conditioning control unit 15 transmits the first signal S1 when the following conditions (1) to (3) are met: (1) the ultraviolet irradiation unit 50 is connected to the air conditioning device 10 (air conditioning control unit 15), (2) there is no abnormality in the indoor unit 20, and (3) the indoor fan 22 is ON. Note that, in the air conditioning device 10 of the present disclosure, a configuration is exemplified in which the air conditioning control unit 15 transmits the first signal S1 when the above conditions (1) to (3) are met, but the air conditioning control unit 15 may be configured to transmit the first signal S1 when only conditions (1) and (2) are met. In this case, the air conditioning control unit 15 can transmit the first signal even if the indoor fan 22 is OFF. In this case, the light source 51 can irradiate ultraviolet rays UV when the indoor fan 22 is OFF.

After transmitting the first signal S1 in step (S104), the air conditioning control unit 15 next executes step (S105). In step (S105), the air conditioning control unit 15 executes a determination as to whether or not the remote control 16 is ON. If the air conditioning control unit 15 determines in step (S105) that the remote control 16 is ON (YES), then it executes step (S106). On the other hand, if the air conditioning control unit 15 determines in step (S105) that the remote control 16 is not ON (NO) (i.e., the air conditioning device 10 is turned OFF), then it executes step (S109).

In step (S106), the air conditioning control unit 15 executes a determination as to whether or not there is an abnormality in the indoor unit 20. If the air conditioning control unit 15 determines in step (S106) that there is no abnormality in the indoor unit 20 (YES), then it executes step (S107). On the other hand, if the air conditioning control unit 15 determines in step (S106) that there is an abnormality in the indoor unit 20 (NO), then it executes step (S109).

In step (S107), the air conditioning control unit 15 executes a determination as to whether or not the indoor fan 22 is ON. If the air conditioning control unit 15 determines in step (S107) that the indoor fan 22 is ON (YES), steps (S105) to (S107) are repeated until the indoor fan 22 is turned OFF. On the other hand, if the air conditioning control unit 15 determines in step (S107) that the indoor fan 22 is not ON (NO) (i.e., the air conditioning device 10 is in an automatic stop state due to the thermostat on/off), step (S108) is then executed.

In step (S108), the air conditioning control unit 15 transmits the second signal S2. The second signal S2 is a signal for stopping optional items attached to the air conditioning device 10, and is a general-purpose signal that corresponds to all optional items that can be attached. In other words, in the air conditioning device 10 of the present disclosure, after transmitting the first signal S1, the air conditioning control unit 15 transmits the second signal S2 if (4) the remote control 16 is ON, and (5) there is no abnormality in the indoor unit 20, but (6) the indoor fan 22 is no longer ON.

In the air conditioning device 10, if the air conditioning device 10 is turned off by the remote control 16 after the first signal S1 is transmitted, or if an abnormality occurs in the indoor unit 20, in step (S109), the air conditioning control unit 15 transmits the second signal S2 and terminates the control operation for the ultraviolet irradiation unit 50.

As described above, in the air conditioning device 10 of the present disclosure, the air conditioning control unit 15 only transmits the first signal S1 that permits operation of the ultraviolet irradiation unit 50 and the second signal S2 that stops operation of the ultraviolet irradiation unit 50. In other words, the air conditioning control unit 15 does not control the operation of the ultraviolet irradiation unit 50 (specifically, the ON-OFF operation of the light source 51).

[Control contents performed by the light source control unit]
Fig. 8 is a control flow diagram of the light source control unit according to the first embodiment. The control operation shown in Fig. 8 is a first embodiment of the control operation for controlling the operation of the light source 51 of the ultraviolet irradiation unit 50. When power is supplied to the ultraviolet irradiation unit 50, the light source control unit 52 (see Fig. 3) starts the control operation shown in Fig. 8.

As shown in FIG. 8, when the light source control unit 52 starts controlling the operation of the light source 51, it executes step (S201). In step (S201), the light source control unit 52 executes a determination as to whether or not the first signal S1 has been input. If the light source control unit 52 determines in step (S201) that the first signal S1 has been input (YES), it then executes step (S202). On the other hand, if the light source control unit 52 determines in step (S201) that the first signal S1 has not been input (NO), it repeatedly executes step (S201) until the first signal S1 is input.

In step (S202), the light source control unit 52 turns on the power source of the light source 51. At this time, in the air conditioning device 10, ultraviolet light UV is irradiated from the light source 51 toward the lower end surface 24c of the collection member 24.

After turning on the power of the light source 51 in step (S202), the light source control unit 52 then executes step (S203). In step (S203), the light source control unit 52 executes a determination as to whether or not the second signal S2 has been input. If the light source control unit 52 determines in step (S203) that the second signal S2 has been input (YES), then it executes step (S204). On the other hand, if the light source control unit 52 determines in step (S203) that the second signal S2 has not been input (NO), then it executes step (S203) repeatedly until the second signal S2 is input.

In step (S204), the light source control unit 52 turns off the power supply to the light source 51. At this time, in the air conditioning device 10, the irradiation of ultraviolet light UV from the light source 51 toward the collection member 24 is stopped.

After turning off the power supply to the light source 51 in step (S204), the light source control unit 52 returns to step (S201) and executes the control operations from step (S201) onwards again.

As described above, in the air conditioning device 10 of the present disclosure, the light source control unit 52 controls the ON/OFF of the power supply to the light source 51.

In the air conditioning device 10 of the present disclosure, it is preferable that the light source control unit 52 turns the power of the light source 51 ON and OFF based on the first information J1 sent from the air conditioning control unit 15. It is known that the lifespan of the light source 51 decreases when used in a high-temperature atmosphere (for example, an atmosphere exceeding 40 degrees). In the air conditioning device 10 of the present disclosure, the light source control unit 52 turns the power of the light source 51 ON and OFF based on the first information J1. Specifically, when the light source control unit 52 detects from the first information J1 that the ambient temperature of the light source 51 exceeds 40 degrees, it turns the power of the light source 51 OFF, and when it detects that the ambient temperature of the light source 51 is less than 40 degrees, it turns the power of the light source 51 ON. In the air conditioning device 10, such a configuration can suppress the decrease in the lifespan of the light source 51. Furthermore, in the air conditioning device 10 configured in this way, there is no need to provide a temperature sensor in the ultraviolet irradiation unit 50, so the configuration of the ultraviolet irradiation unit 50 can be simplified. In addition, the air conditioning device 10 may be configured to incorporate the first information J1 into the conditions for transmitting the first signal S1, so that the air conditioning control unit 15 transmits the first signal S1 when it is determined from the detection value of the indoor temperature sensor 41 that the ambient temperature of the light source 51 is less than 40 degrees.

Figure 9 is a control flow diagram of the light source control unit according to the second embodiment. The control operation shown in Figure 9 is a second embodiment of the control operation for controlling the operation of the light source 51 of the ultraviolet irradiation unit 50. In the air conditioning device 10, the light source control unit 52 (see Figure 3) may control the operation of the light source 51 according to the flow shown in Figure 9. The control flow of the light source control unit 52 according to the second embodiment differs from the control flow of the light source control unit 52 according to the first embodiment (see Figure 8) in that it includes steps (S200) and (S205). Here, the configurations that differ from the flow shown in Figure 8 will be described, and a description of the common configurations will be omitted.

As shown in FIG. 9, when the light source control unit 52 starts controlling the operation of the light source 51, it executes step (S200). In step (S200), the light source control unit 52 executes a determination as to whether or not there is an abnormality in the light source 51. If the light source control unit 52 determines in step (S200) that there is no abnormality in the light source 51 (YES), it then executes step (S201). On the other hand, if the light source control unit 52 determines in step (S200) that there is an abnormality in the light source 51 (NO), it then executes step (S205).

In step (S205), the light source control unit 52 transmits the third signal S3. When the third signal S3 is input, the air conditioning control unit 15 causes the notification unit 60 to issue a notification.

As described above, in the air conditioning device 10 of the present disclosure, when the light source control unit 52 detects an abnormality in the light source 51, it transmits a third signal S3, and upon receiving the third signal S3, the air conditioning control unit 15 causes the notification unit 60 to issue a notification.

Figure 10 is a control flow diagram of the light source control unit according to the third embodiment. The control operation shown in Figure 10 is a third embodiment of the control operation for controlling the operation of the light source 51 of the ultraviolet irradiation unit 50. In the air conditioning device 10, the light source control unit 52 (see Figure 3) may control the operation of the light source 51 according to the flow shown in Figure 10.

As shown in FIG. 10, when the light source control unit 52 starts controlling the operation of the light source 51, it executes step (S211). In step (S211), the light source control unit 52 executes a determination as to whether or not the first signal S1 has been input. If the light source control unit 52 determines in step (S211) that the first signal S1 has been input (YES), it then executes step (S212). On the other hand, if the light source control unit 52 determines in step (S211) that the first signal S1 has not been input (NO), it repeatedly executes step (S211) until the first signal S1 is input.

In step (S212), the light source control unit 52 turns on the power source of the light source 51. At this time, in the air conditioning device 10, ultraviolet light UV is irradiated from the light source 51 toward the lower end surface 24c of the collection member 24.

After turning on the power of the light source 51 in step (S212), the light source control unit 52 next executes step (S213). In step (S213), the light source control unit 52 executes a determination as to whether or not a first predetermined period X1 has elapsed after turning on the power of the light source 51. If the light source control unit 52 determines in step (S213) that the first predetermined period X1 has elapsed (YES), then it executes step (S215). On the other hand, if the light source control unit 52 determines in step (S213) that the first predetermined period X1 has not elapsed (NO), then it executes step (S214).

In step (S214), the light source control unit 52 executes a determination as to whether or not the second signal S2 has been input. If the light source control unit 52 determines in step (S214) that the second signal S2 has been input (YES), then it executes step (S215). On the other hand, if the light source control unit 52 determines in step (S214) that the second signal S2 has not been input (NO), it repeatedly executes steps (S213) and (S214) until the second signal S2 is input.

In step (S215), the light source control unit 52 turns off the power of the light source 51. After turning off the power of the light source 51 in step (S215), the light source control unit 52 then executes step (S216). In this way, in the air conditioning device 10, the power of the light source 51 may be turned off when the first predetermined time X1 has elapsed after the power of the light source 51 is turned on, regardless of whether the second signal S2 is input or not.

In step (S216), the light source control unit 52 executes a determination as to whether or not the second predetermined period X2 has elapsed since the power supply of the light source 51 was turned off. In step (S216), if the light source control unit 52 determines that the second predetermined period X2 has elapsed (YES), the process returns to step (S211). On the other hand, in step (S216), if the light source control unit 52 determines that the second predetermined period X2 has not elapsed (NO), the process repeats step (S216) until the second predetermined period X2 has elapsed.

When the air conditioning device 10 employs the control flow shown in FIG. 10, for example, the light source 51 can be controlled to be ON for 3 hours, OFF for 3 hours, and ON for another 3 hours, for a total of 6 hours. This makes it easy to set an upper limit on the irradiation time of the light source 51 per day. In this case, the power supply of the light source 51 can be controlled ON-OFF using only the functions of the light source control unit 52. In the air conditioning device 10, it is more preferable to lengthen the first predetermined period X1 in accordance with the increase in the usage time, taking into account the deterioration of the light source 51 with the increase in the usage time. This makes it possible to ensure a predetermined irradiation intensity even when using a light source 51 that has been used for a long time, and to suppress a decrease in sterilization performance.

As described above, in the air conditioning device 10 of the present disclosure, the light source control unit 52 can turn on the power of the light source 51 for a first predetermined period X1 and then turn it off for a second predetermined period X2.

Figure 11 is a control flow diagram of the light source control unit according to the fourth embodiment. The control operation shown in Figure 11 is a fourth embodiment of the control operation for controlling the operation of the light source 51 of the ultraviolet irradiation unit 50. In the air conditioning device 10, the light source control unit 52 (see Figure 3) may control the operation of the light source 51 according to the flow shown in Figure 11.

As shown in FIG. 11, when the light source control unit 52 starts the control operation of the light source 51, it first executes step (S220) to reset the accumulated irradiation time T of the light source 51 to "0", and then executes step (S221).

In step (S221), the light source control unit 52 executes a determination as to whether or not the first signal S1 has been input. If the light source control unit 52 determines in step (S211) that the first signal S1 has been input (YES), then it executes step (S222). On the other hand, if the light source control unit 52 determines in step (S221) that the first signal S1 has not been input (NO), it repeatedly executes step (S221) until the first signal S1 is input.

In step (S222), the light source control unit 52 executes a determination as to whether or not the accumulated irradiation time T of the light source 51 is less than a predetermined threshold Y. If the light source control unit 52 determines in step (S222) that the accumulated irradiation time T of the light source 51 is less than the predetermined threshold Y (YES), then it executes step (S223). On the other hand, if the light source control unit 52 determines in step (S222) that the accumulated irradiation time T of the light source 51 has exceeded the predetermined threshold Y (NO), then it executes step (S229).

In step (S223), the light source control unit 52 turns on the power of the light source 51. At this time, in the air conditioning device 10, ultraviolet light UV is irradiated from the light source 51 toward the lower end surface 24c of the collection member 24.

After turning on the power of the light source 51 in step (S223), the light source control unit 52 executes step (S224). In step (S224), the light source control unit 52 starts accumulating the irradiation time of ultraviolet light UV by the light source 51, and then executes step (S225).

In step (S225), the light source control unit 52 executes a determination as to whether or not the accumulated irradiation time T of the light source 51 is less than a predetermined threshold Y. If the light source control unit 52 determines in step (S225) that the accumulated irradiation time T of the light source 51 is less than the predetermined threshold Y (YES), then it executes step (S226). On the other hand, if the light source control unit 52 determines in step (S225) that the accumulated irradiation time T of the light source 51 has exceeded the predetermined threshold Y (NO), then it executes step (S227).

In step (S227), the light source control unit 52 resets the accumulated irradiation time T of the light source 51 to "0", and then executes step (S228).

In step (S226), the light source control unit 52 executes a determination as to whether or not the second signal S2 has been input. If the light source control unit 52 determines in step (S226) that the second signal S2 has been input (YES), then it executes step (S228). On the other hand, if the light source control unit 52 determines in step (S226) that the second signal S2 has not been input (NO), it repeatedly executes steps (S225) to (S226) until the second signal S2 is input.

In step (S228), the light source control unit 52 turns off the power supply to the light source 51. After turning off the light source 51 in step (S228), the light source control unit 52 executes step (S230). Similarly, when proceeding from step (S222) to step (S229), the light source control unit 52 resets the accumulated irradiation time T of the light source 51 to "0" and then executes step (S230).

In step (S230), the light source control unit 52 executes a judgment as to whether or not it is a timing when the light source 51 can irradiate ultraviolet rays UV. In step (S230), if the light source control unit 52 judges that it is a timing when the light source 51 can irradiate ultraviolet rays UV (YES), the process returns to step (S221). On the other hand, in step (S230), if the light source control unit 52 judges that it is not a timing when the light source 51 can irradiate ultraviolet rays UV (NO), the process repeats step (S230) until it is a timing when the light source 51 can irradiate ultraviolet rays UV.

In the ultraviolet irradiation unit 50, an upper limit for the irradiation time per day is set, taking into consideration the lifespan of the light source 51. When the irradiation time of ultraviolet rays UV by the light source 51 on a certain day has not reached the upper limit, this corresponds to a time when irradiation of ultraviolet rays UV by the light source 51 is possible. On the other hand, when the irradiation time of ultraviolet rays UV by the light source 51 has reached the upper limit, this corresponds to a time when irradiation of ultraviolet rays UV by the light source 51 is not possible. If the irradiation time per day exceeds the upper limit threshold Y and the light source is turned OFF through steps (S227) and (S229), irradiation by the light source cannot be performed on that day, so in step (S230), the system waits until the next day.

As described above, in the air conditioning device 10 of the present disclosure, the light source control unit 52 controls the ON/OFF of the power supply of the light source 51 according to the accumulated irradiation time T of the light source 51.

[Effects of the embodiment]
(1) The ultraviolet irradiation unit 50 of the above embodiment can be attached to an air conditioning apparatus 10 including an indoor unit 20 having an indoor fan 22, and an air conditioning control unit 15 that controls the operation of the indoor unit 20. The ultraviolet irradiation unit 50 includes a light source 51 that irradiates the indoor unit 20 with ultraviolet rays UV, and a light source control unit 52 that can communicate with the air conditioning control unit 15 and controls the operation of the light source 51. In the ultraviolet irradiation unit 50, when the light source control unit 52 receives a first signal S1 transmitted from the air conditioning control unit 15, it turns on the power supply of the light source 51.

With an ultraviolet irradiation unit 50 configured in this way, there is no need to previously store a control program for controlling the ultraviolet irradiation unit 50 in the air conditioning control unit 15 of the air conditioning device 10 to which the ultraviolet irradiation unit 50 can be attached. This simplifies the configuration of the air conditioning control unit 15 of the air conditioning device 10.

(2) In the ultraviolet irradiation unit 50 of the above embodiment, the light source control unit 52 turns off the power supply of the light source 51 when the first predetermined period X1 has elapsed after receiving the first signal S1.

In this case, the light source 51 can be easily turned on and off by the light source control unit 52. The configuration of the light source control unit 52 of the ultraviolet irradiation unit 50 can be simplified.

(3) In the ultraviolet irradiation unit 50 of the above embodiment, when the light source control unit 52 receives the second signal S2 transmitted from the air conditioning control unit 15 when the air conditioning device 10 stops operating or when the indoor fan 22 stops operating, the light source control unit 52 turns off the power supply to the light source 51.

In this case, the light source control unit 52 can easily turn the light source 51 on and off depending on the operating state of the air conditioning device 10.

(4) The air conditioning device 10 of the above embodiment includes an indoor unit 20 having a casing 21 with an inlet 25 for drawing in indoor air, an indoor fan 22 housed in the casing 21, and a collection member 24 housed in the casing 21, an air conditioning control unit 15 that controls the operation of the indoor unit 20, an ultraviolet irradiation unit 50 having a light source 51 that irradiates the collection member 24 with ultraviolet light, and a light source control unit 52 that can communicate with the air conditioning control unit 15 and controls the operation of the light source 51. In the air conditioning device 10, when the light source control unit 52 receives a first signal S1 transmitted from the air conditioning control unit 15, it turns on the power of the light source 51.

According to the air conditioning device 10 of the present disclosure, it is not necessary to store in advance a control program for controlling the ultraviolet irradiation unit 50 in the air conditioning control unit 15. Therefore, in the air conditioning device 10, the configuration of the air conditioning control unit 15 can be simplified.

(5) In the air conditioning device 10 of the above embodiment, when the operation of the air conditioning device 10 is started or when the operation of the indoor fan 22 is started, the air conditioning control unit 15 transmits the first signal S1.

In this case, the configuration of the air conditioning control unit 15 can be simplified.

(6) In the air conditioning device 10 of the above embodiment, the light source control unit 52 turns off the power supply to the light source 51 after the first predetermined period X1 has elapsed after receiving the first signal S1.

In this case, the light source control unit 52 can easily turn the light source 51 on and off depending on the operating state of the air conditioning device 10.

(7) In the air conditioning device 10 of the above embodiment, when the air conditioning device 10 stops operating or when the indoor fan 22 stops operating, the air conditioning control unit 15 transmits a second signal S2, and when the light source control unit 52 receives the second signal S2, it turns off the power supply to the light source 51.

In this case, the configuration of the light source control unit 52 can be simplified.

(8) The air conditioning device 10 of the above embodiment further includes an alarm unit 60. In the air conditioning device 10, the air conditioning control unit 15 transmits a third signal S3 to the air conditioning control unit when it detects an abnormality in the light source 51, and causes the alarm unit 60 to issue an alarm when the air conditioning control unit 15 receives the third signal S3.

In this case, the notification unit 60 can notify the user that an abnormality has occurred in the light source 51.

(9) In the air conditioning device 10 of the above embodiment, the light source control unit 52 receives first information J1 regarding the indoor temperature from the air conditioning control unit 15, and turns the power of the light source 51 on and off based on the first information J1.

In this case, the simple configuration of the light source control unit 52 can suppress deterioration of the light source 51 due to the influence of the ambient temperature.

The present disclosure is not limited to the above examples, but is intended to include all modifications within the scope and meaning equivalent to the claims.

10: Air conditioner 15: Air conditioning control unit 20: Indoor unit 21: Casing 22: Indoor fan 24: Collection member 25: Intake port 50: Ultraviolet irradiation unit 51: Light source 52: Light source control unit 60: Notification unit S1: First signal S2: Second signal S3: Third signal J1: First information X1: First predetermined period (predetermined period)

Claims (12)

An ultraviolet irradiation unit (50) that can be attached to an air conditioner (10) including an indoor unit (20) having an indoor fan (22) and an air conditioning control unit (15) that controls the operation of the indoor unit (20),
a light source (51) for irradiating the indoor unit (20) with ultraviolet (UV) rays;
a light source control unit (52) capable of communicating with the air conditioning control unit (15) and controlling the operation of the light source (51);
Equipped with
When the light source control unit (52) receives a first signal (S1) that permits operation of the ultraviolet irradiation unit (50) transmitted from the air conditioning control unit (15), the light source control unit (52) turns on the power of the light source (51), and when the light source control unit (52) receives the first signal (S1) within a predetermined period (X2) after the power of the light source (51) is turned off, the light source control unit (52) does not turn on the power of the light source (51). The ultraviolet irradiation unit (50) of claim 1, wherein the light source control unit (52) turns off the power supply of the light source (51) when a predetermined period (X1) has elapsed after receiving the first signal (S1). The ultraviolet irradiation unit (50) according to claim 1 or 2, wherein the light source control unit (52) turns off the power supply of the light source (51) when the air conditioning device (10) stops operating or when the indoor fan (22) stops operating and receives a second signal (S2) transmitted from the air conditioning control unit (15). 2. The ultraviolet irradiation unit (50) according to claim 1, wherein the first signal (S1) is transmitted when operation of the air conditioning device (10) is started and there is no abnormality in the indoor unit (20) , or when operation of the indoor fan (22) is started. The ultraviolet irradiation unit (50) according to claim 1, wherein the light source control unit (52) receives first information (J1) regarding the indoor temperature from the air conditioning control unit (15), and the light source control unit (52) turns on the power supply of the light source (51) based on the first information (J1). An indoor unit (20) including a casing (21) having an inlet (25) for sucking indoor air, an indoor fan (22) housed in the casing (21), and a collection member (24) housed in the casing (21);
An air conditioning control unit (15) for controlling the operation of the indoor unit (20);
an ultraviolet irradiation unit (50) including a light source (51) that irradiates the collection member (24) with ultraviolet (UV) rays, and a light source control unit (52) that is capable of communicating with the air conditioning control unit (15) and controls the operation of the light source (51);
Equipped with
When the light source control unit (52) receives a first signal (S1) that permits operation of the ultraviolet irradiation unit (50) transmitted from the air conditioning control unit (15), it turns on the power of the light source (51), and if the light source control unit (52) receives the first signal (S1) within a predetermined period (X2) after the power of the light source (51) is turned off, it does not turn on the power of the light source (51). When the operation of the air conditioning device (10) is started and there is no abnormality in the indoor unit (20) , or when the operation of the indoor fan (22) is started,
The air conditioner (10) according to claim 6, wherein the air conditioning control unit (15) transmits the first signal (S1). The air conditioner (10) according to claim 6 or 7, wherein the light source control unit (52) turns off the power supply to the light source (51) after a predetermined period (X1) has elapsed after receiving the first signal (S1). When the air conditioner (10) stops operating, or when the indoor fan (22) stops operating, the air conditioning control unit (15) transmits a second signal (S2),
The air conditioner (10) according to any one of claims 6 to 8, wherein the light source control unit (52) turns off the power supply of the light source (51) when the second signal (S2) is received. Further comprising a notification unit (60),
When the light source control unit (52) detects an abnormality in the light source (51), it transmits a third signal (S3) to the air conditioning control unit (15),
The air conditioner (10) according to any one of claims 6 to 9, wherein the air conditioning control unit (15) causes the notification unit (60) to provide notification when the third signal (S3) is received. The light source control unit (52) receives first information (J1) regarding an indoor temperature from the air conditioning control unit (15),
The air conditioner (10) according to any one of claims 6 to 10, wherein the light source control unit (52) turns on and off the power supply of the light source (51) based on the first information (J1). An air conditioner (10) according to any one of claims 6 to 10, wherein the air conditioning control unit (15) incorporates first information (J1) relating to the indoor temperature into the transmission conditions of the first signal (S1) and transmits the first information (J1).

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