JP7348538B2 - Diagnostic system, diagnostic method, diagnostic program, and air conditioner - Google Patents

Description

The present disclosure relates to a diagnostic system, a diagnostic method, a diagnostic program, and an air conditioner.

BACKGROUND ART Conventionally, an air conditioner is known that includes a refrigerant circuit including a compressor, a heat exchanger, a four-way switching valve, an expansion valve, etc., and performs cooling operation and heating operation (see Patent Document 1). The air conditioner described in Patent Document 1 is provided with a temperature sensor that detects the temperature of the refrigerant and the temperature of the air, and the detected values of these temperature sensors are used to control the operation of the air conditioner.

Japanese Patent Application Publication No. 11-237097

Various sensors such as temperature sensors installed in air conditioners may gradually deviate from their normal values (“detection deviation”), and if this deviation becomes too large, the air conditioner may not be controlled properly. There is a risk that it may interfere with driving. Therefore, it is desirable to know the detection status of such sensors.

The present disclosure aims to provide a diagnostic system and an air conditioner that can diagnose the detection state of a sensor.

(1) The diagnostic system of the present disclosure acquires the detected value of a sensor provided in the air conditioner while the air conditioner is stopped, and calculates the detected value or a calculated value obtained from the detected value and a predetermined reference value. The sensor includes a processing unit that diagnoses the detection state of the sensor based on a comparison with the sensor.

While the air conditioner is stopped, the detected value of the sensor provided in the air conditioner is considered to converge to a certain value depending on the surrounding environment. In the present disclosure, the detected value of the sensor to be diagnosed is acquired while the air conditioner is stopped, and the detected value or the calculated value obtained from the detected value and the value that is expected to converge (reference value) are calculated. By comparing the values, it is possible to understand how much the sensor deviates from the normal state, and the detection state of the sensor can be diagnosed from the magnitude of the deviation.

(2) Preferably, the sensor is a temperature sensor.
When the air conditioner is stopped, the detected value of the temperature sensor installed in the air conditioner converges to the surrounding temperature, so by comparing the detected value of the temperature sensor with the reference value corresponding to the surrounding temperature, , it is possible to grasp the extent to which the temperature sensor deviates from its normal state.

(3) Preferably, the reference value is determined from detection values of a plurality of temperature sensors provided in the air conditioner.
According to this configuration, by determining the reference value from the detected value of the temperature sensor provided in the air conditioner, it is possible to set an appropriate reference value according to the environment around the installation location of the air conditioner.

(4) Preferably, the reference value is a median value of values detected by a plurality of temperature sensors provided in the air conditioner.
According to the above configuration, by using the median value of the detected values of the plurality of temperature sensors as the reference value, even if the detected values include an abnormal value, that value is suppressed from having an adverse effect on the reference value. can do.

(5) Preferably, the reference value is an average value of detection values of a plurality of temperature sensors provided in the air conditioner.

(6) Preferably, the average value is obtained by omitting a maximum value and a minimum value of the detected values of the plurality of temperature sensors.
According to this configuration, when the detected values of the plurality of temperature sensors include abnormally large or small values, it is possible to prevent the values from adversely affecting the reference value.

(7) Preferably, the sensor to be diagnosed is one of the plurality of temperature sensors.
According to this configuration, the sensor itself to be diagnosed can be used as a temperature sensor for determining the reference value.

(8) Preferably, the reference value is a detection value of an ambient temperature sensor that detects the ambient temperature of the air conditioner;
The sensor to be diagnosed is a temperature sensor other than the ambient temperature sensor.

(9) Preferably, the sensor is a pressure sensor that detects the pressure of the refrigerant.
While the air conditioner is stopped, the detected value of the pressure sensor provided in the air conditioner converges to a value corresponding to the surrounding environment. Therefore, by comparing the detected value of the pressure sensor or the calculated value obtained from the detected value with a reference value depending on the surrounding environment, it is possible to understand how much the pressure sensor deviates from its normal state. can do.

(10) Preferably, the processing unit obtains a pressure equivalent saturation temperature as the calculated value from the detected value of the sensor.

(11) Preferably, the reference value is determined from detection values of a plurality of temperature sensors provided in the air conditioner.

(12) Preferably, when a difference between the detected value of the sensor or the calculated value and the reference value exceeds a threshold, the processing unit calculates a correction value according to the difference, and Instructs operation control using correction values.
According to this configuration, even if there is a deviation in the detected value of the sensor, the operation of the air conditioner can be continued as an emergency measure.

(13) An air conditioner of the present disclosure includes the diagnostic system according to any one of (1) to (12) above.

(14) The diagnostic method of the present disclosure includes a step of acquiring a detected value of a sensor provided in the air conditioner while the air conditioner is stopped, and a step of acquiring a detected value of a sensor provided in the air conditioner, and based on the detected value or a calculated value obtained from the detected value. , diagnosing the detection state of the sensor.

(15) The diagnostic program of the present disclosure includes a step of acquiring a detected value of a sensor provided in the air conditioner while the air conditioner is stopped;
A computer is caused to execute a procedure for diagnosing the detection state of the sensor based on the detected value or a calculated value obtained from the detected value.

1 is a configuration diagram of an air conditioning system according to an embodiment of the present disclosure. It is a schematic refrigerant circuit diagram of an air conditioner. It is a block diagram of an outdoor control part. 3 is a table illustrating the contents of abnormality information, retry information, and predictive information stored in a storage unit. It is a table showing an example of detection of a sign of abnormality. 7 is a table illustrating the contents of abnormality information displayed on a display unit. 3 is a table illustrating the contents of retry information displayed on a display unit. It is a table illustrating the contents of predictive information displayed on the display unit. It is a flowchart which shows the procedure of diagnosing the detection gap of a temperature sensor. It is a flowchart which shows the procedure of diagnosing the detection gap of a pressure sensor.

Hereinafter, embodiments of an air conditioning system will be described in detail with reference to the accompanying drawings.
FIG. 1 is a configuration diagram of an air conditioning system according to an embodiment of the present disclosure.
As shown in FIG. 1, the air conditioning system includes an air conditioner 11, a central management device 50, and a management server 62. The air conditioner 11 adjusts the temperature of indoor air, which is a space to be air-conditioned, to a predetermined target temperature. The air conditioner 11 of this embodiment performs indoor cooling and heating.

The air conditioner 11 includes an indoor unit 21 and an outdoor unit 22. This air conditioner 11 is, for example, a multi-type air conditioner 11 in which a plurality of indoor units 21 are connected in parallel to an outdoor unit 22. However, the air conditioner 11 may include one outdoor unit 22 and one indoor unit 21.

FIG. 2 is a schematic refrigerant circuit diagram of the air conditioner.
As shown in FIG. 2, the air conditioner 11 has a refrigerant circuit 23. The refrigerant circuit 23 circulates refrigerant between the indoor unit 21 and the outdoor unit 22. The refrigerant circuit 23 includes a compressor 30, an oil separator 31, a four-way switching valve 32, an outdoor heat exchanger (heat source heat exchanger) 33, an outdoor expansion valve 34, a subcooler 35, a liquid closing valve 36, and an indoor expansion valve. 24, an indoor heat exchanger (utilization heat exchanger) 25, a gas shutoff valve 37, an accumulator 38, and refrigerant pipes 40L and 40G connecting these.

The indoor unit 21 includes an indoor expansion valve 24 and an indoor heat exchanger 25 that constitute a refrigerant circuit 23 . The indoor expansion valve 24 is constituted by an electric valve that can adjust the flow rate of refrigerant. The indoor heat exchanger 25 is a cross-fin tube type or microchannel type heat exchanger, and is used to exchange heat with indoor air.

The indoor unit 21 further includes an indoor fan 26 and an indoor temperature sensor 27. The indoor fan 26 is configured to take indoor air into the interior of the indoor unit 21, perform heat exchange between the taken air and the indoor heat exchanger 25, and then blow out the air indoors. . The indoor fan 26 includes a motor whose operating speed can be adjusted by inverter control. The indoor temperature sensor 27 detects the indoor temperature.

The outdoor unit 22 includes a compressor 30, an oil separator 31, a four-way switching valve 32, an outdoor heat exchanger 33, an outdoor expansion valve 34, a subcooler 35, a liquid shut-off valve 36, and a gas shut-off valve, which constitute a refrigerant circuit 23. 37, and an accumulator 38.

The compressor 30 sucks in low-pressure gas refrigerant and discharges high-pressure gas refrigerant. The compressor 30 includes a motor whose operating speed can be adjusted by inverter control. The compressor 30 is a variable capacity type (capacity variable type) whose capacity (capacity) can be changed by controlling the motor with an inverter. However, the compressor 30 may be of a constant capacity type. A plurality of compressors 30 may be provided. In this case, the variable capacity compressor 30 and the constant capacity compressor 30 may coexist.

The oil separator 31 separates refrigeration oil contained in the refrigerant discharged from the compressor 30 from the refrigerant. Refrigerating machine oil separated by the oil separator 31 is returned to the compressor 30 via an oil return pipe 41. The oil return pipe 41 is provided with an on-off valve 42 . The on-off valve 42 consists of a solenoid valve. When the on-off valve 42 is opened, the refrigerating machine oil in the oil separator 31 passes through the oil return pipe 41 and is sucked into the compressor 30 together with the refrigerant flowing through the suction pipe 44 .

The four-way switching valve 32 reverses the flow of refrigerant in the refrigerant pipe, and switches and supplies the refrigerant discharged from the compressor 30 to either the outdoor heat exchanger 33 or the indoor heat exchanger 25. Thereby, the air conditioner 11 can switch between cooling operation and heating operation.

The outdoor heat exchanger 33 is, for example, a cross-fin tube type or microchannel type heat exchanger, and uses air as a heat source to exchange heat with a refrigerant and condense or evaporate the refrigerant.
The outdoor expansion valve 34 is constituted by an electrically operated valve that can adjust the flow rate of refrigerant.

The supercooler 35 supercools the refrigerant condensed in the outdoor heat exchanger 33. The supercooler 35 has a first heat exchanger tube 35a and a second heat exchanger tube 35b. One end of the first heat transfer tube 35a is connected to a refrigerant pipe extending to the outdoor expansion valve 34. The other end of the first heat transfer tube 35a is connected to a refrigerant pipe extending to the liquid shutoff valve 36. One end of the second heat transfer tube 35b is connected to a branch pipe 35c that branches from the refrigerant pipe between the first heat transfer tube 35a and the outdoor expansion valve 34. An expansion valve 43 is provided in the branch pipe 35c. The other end of the second heat transfer tube 35b is connected to a suction pipe 44 for returning refrigerant to the compressor 30.

The supercooler 35 allows the refrigerant to flow from the compressor 30 through the outdoor heat exchanger 33 and the expansion valve 34 to the first heat transfer tube 35a, and the refrigerant whose pressure is reduced by the expansion valve 43 to flow through the second heat transfer tube 35b. Heat exchange is performed between the first heat transfer tubes 35a, and the refrigerant flowing through the first heat transfer tubes 35a is supercooled. The refrigerant flowing through the second heat transfer tube 35b passes through the suction pipe 44, passes through the accumulator 38, and is sucked into the compressor 30.

The accumulator 38 temporarily stores the low-pressure refrigerant sucked into the compressor 30 and separates the gas refrigerant and the liquid refrigerant. The accumulator 38 is provided in the suction pipe 44. One end of an oil return pipe 45 is connected to the accumulator 38 . The other end of the oil return pipe 45 is connected to the suction pipe 44. The oil return pipe 45 is a pipe for returning refrigerating machine oil from the accumulator 38 to the compressor 30. The oil return pipe 45 is provided with an on-off valve 46 . The on-off valve 46 consists of a solenoid valve. When the on-off valve 46 is opened, the refrigerating machine oil in the accumulator 38 passes through the oil return pipe 45 and is sucked into the compressor 30 together with the refrigerant flowing through the suction pipe 44 .

The liquid shutoff valve 36 is a manual on-off valve. The gas shutoff valve 37 is also a manual on-off valve. The liquid shutoff valve 36 and the gas shutoff valve 37 block the flow of refrigerant in the refrigerant pipes 40L, 40G by closing, and allow the flow of refrigerant in the refrigerant pipes 40L, 40G by opening.

The outdoor unit 22 further includes an outdoor fan 39, pressure sensors 51 and 52, temperature sensors 53 to 59, a current sensor 60, and the like. The outdoor fan 39 includes a motor whose operating rotation speed can be adjusted by inverter control. The outdoor fan 39 takes outdoor air into the outdoor unit 22 , exchanges heat between the taken air and the outdoor heat exchanger 33 , and then blows the air out of the outdoor unit 22 . It is configured.

The pressure sensors 51 and 52 include a suction pressure sensor 51 and a discharge pressure sensor 52. The suction pressure sensor 51 detects the pressure of refrigerant sucked into the compressor 30. The discharge pressure sensor 52 detects the pressure of refrigerant discharged from the compressor 30.

The temperature sensors 53 to 59 include refrigerant temperature sensors 53 to 57 that detect the temperature of the refrigerant, an outside air temperature sensor 58 that detects the temperature of the outside air, and a temperature sensor 59 that detects the surface temperature of the compressor 30. Refrigerant temperature sensor 53 detects the temperature of refrigerant sucked into compressor 30. Refrigerant temperature sensor 54 detects the temperature of refrigerant discharged from compressor 30. The refrigerant temperature sensor 55 detects the temperature of the refrigerant on the liquid side of the outdoor heat exchanger 33. Refrigerant temperature sensor 56 detects the temperature of the refrigerant between supercooler 35 and liquid shutoff valve 36 . The refrigerant temperature sensor 57 detects the temperature of the refrigerant flowing out from the second heat transfer tube 35b of the subcooler 35.

Using the detected values of the suction pressure sensor 51, discharge pressure sensor 52, and refrigerant temperature sensors 53 and 54, the evaporation temperature and condensation temperature of the refrigerant in the outdoor heat exchanger 33 and the indoor heat exchanger 25, the degree of superheating of the refrigerant, etc. are determined. The rotational speed of the compressor 30, the opening degrees of the outdoor expansion valve 34, the indoor expansion valve 24, etc. are controlled to adjust these values.

When the air conditioner 11 configured as described above performs cooling operation, the four-way switching valve 32 is maintained in the state shown by the solid line in FIG. The high-temperature, high-pressure gaseous refrigerant discharged from the compressor 30 flows into the outdoor heat exchanger 33 via the four-way switching valve 32, and is condensed and liquefied by exchanging heat with outdoor air by the operation of the outdoor fan 39. The liquefied refrigerant flows into the indoor unit 21 through the outdoor expansion valve 34 and supercooler 35 which are fully open. In the indoor unit 21, the refrigerant is reduced in pressure to a predetermined low pressure by the indoor expansion valve 24, and further exchanges heat with indoor air in the indoor heat exchanger 25 and evaporates. The indoor air cooled by the evaporation of the refrigerant is blown into the room by the indoor fan 26 to cool the room. The refrigerant evaporated in the indoor heat exchanger 25 returns to the outdoor unit 22 through the gas refrigerant pipe 40G, and is sucked into the compressor 30 through the four-way switching valve 32. The air conditioner 11 also operates in the same manner as the cooling operation when performing a defrost operation to remove frost attached to the outdoor heat exchanger 33.

When the air conditioner 11 performs heating operation, the four-way switching valve 32 is maintained in the state shown by the broken line in FIG. The high-temperature, high-pressure gaseous refrigerant discharged from the compressor 30 passes through the four-way switching valve 32 and flows into the indoor heat exchanger 25 of the indoor unit 21 . In the indoor heat exchanger 25, the refrigerant exchanges heat with indoor air to condense and liquefy. Indoor air heated by the condensation of the refrigerant is blown into the room by the indoor fan 26, heating the room. The refrigerant liquefied in the indoor heat exchanger 25 returns to the outdoor unit 22 through the liquid refrigerant pipe 40L, is reduced in pressure to a predetermined low pressure by the outdoor expansion valve 34, and is further heat exchanged with outdoor air in the outdoor heat exchanger 33. Evaporate. The refrigerant evaporated and vaporized in the outdoor heat exchanger 33 is sucked into the compressor 30 through the four-way switching valve 32.

The indoor unit 21 further includes an indoor control section 29 and a remote controller (remote controller) 29A. The indoor control unit 29 is constituted by a microcomputer or the like having a calculation unit such as a CPU and a storage unit such as a RAM or ROM. The indoor control unit 29 may include an integrated circuit such as FPGA or ASIC. The detected values of each sensor provided in the indoor unit 21 are input to the indoor control section 29. The indoor control unit 29 controls the operation of the indoor expansion valve 24 and the indoor fan 26 based on the detected values of the indoor temperature sensor 27 and the like.

The remote controller 29A is used for inputting instructions to start and stop the operation of the air conditioner 11, inputting operation modes such as cooling and heating, inputting the indoor temperature setting, and the like. The remote controller 29A has a display section 29A1 (see FIG. 3) that displays settings and the like. This display section 29A1 also functions as a notification section for notifying the user of the occurrence of an abnormality, as will be described later.

The outdoor unit 22 further includes an outdoor control section 70. The outdoor control unit 70 is constituted by a microcomputer or the like having a calculation unit such as a CPU and a storage unit such as a RAM or ROM. The outdoor control section 70 exhibits a predetermined function by a calculation section executing a program stored in a storage section. The outdoor control unit 70 may include an integrated circuit such as FPGA or ASIC. Detection values of various sensors 51 to 60 provided in the outdoor unit 22 are inputted to the outdoor control section 70. The outdoor control unit 70 controls the operations of the compressor 30, the outdoor fan 39, the expansion valves 34, 43, etc. based on the detected values of various sensors 51-60. The outdoor control unit 70 also functions as an abnormality diagnosis system for diagnosing the presence or absence of an abnormality in the air conditioner 11, as will be described later.

The indoor control unit 29, the outdoor control unit 70, and the central management device 50 are connected via a local communication network such as a LAN (local area network). Specifically, the indoor control section 29 and the outdoor control section 70 are connected to each other via a transmission line so that they can communicate with each other. The indoor control section 29 and the outdoor control section 70 are connected to the central management device 50 via a transmission line so as to be able to communicate with each other.

The central management device 50 includes a control unit 50a such as a microcomputer having a calculation unit such as a CPU and a storage unit such as ROM and RAM. The control unit 50a performs a predetermined function by having a calculation unit execute a program stored in a storage unit. The control unit 50a may include an integrated circuit such as FPGA or ASIC. The central control device 50 is installed, for example, in a central control room of a building. The centralized management device 50 manages the outdoor unit 22 and the indoor unit 21. Specifically, the central management device 50 monitors the operating status of the outdoor unit 22 and the indoor unit 21, sets the air conditioning temperature, controls operation/stopping, etc. using the control unit 50a.

The management server 62 is provided in a remote location away from the building where the air conditioner 11 is installed. The management server 62 is configured by, for example, a personal computer including a control unit 62a having a calculation unit such as a CPU and a storage unit such as a ROM or RAM. The control unit 62a performs a predetermined function by having the arithmetic unit execute a program stored in the storage unit. The control unit 62a may include an integrated circuit such as an FPGA or an ASIC. The central management device 50 and the management server 62 are communicably connected via a wide area communication network 63 such as the Internet.

In the air conditioning system of this embodiment, the central management device 50 and the management server 62 may be omitted.

[Abnormality diagnosis system]
The outdoor control unit 70 constitutes an abnormality diagnosis system that detects the occurrence of an "abnormality" occurring in the air conditioner 11 and the occurrence of a "premonition of an abnormality" (hereinafter also simply referred to as "premonition"). ing. The outdoor control unit 70 acquires detection values of various sensors 51 to 60 and control data of the compressor 30, outdoor fan 39, expansion valves 34, 43, etc. as operating data. The outdoor control unit 70 uses the acquired operating data to control the operations of various devices such as the compressor 30 and to detect abnormalities and signs of the air conditioner 11.

Devices to be detected for the occurrence of abnormalities and signs include, for example, the compressor 30, the outdoor fan 39, the expansion valves 34 and 43, the temperature sensors 53 to 59, the pressure sensors 51 and 52, and the like. The outdoor control unit 70 stops the air conditioner 11 when detecting the occurrence of an "abnormality" in the air conditioner 11. When the outdoor control unit 70 detects the occurrence of a "sign of abnormality" in the air conditioner 11, it continues to operate the air conditioner 11.

The outdoor control unit 70 executes a retry operation in which the air conditioner 11 is temporarily stopped when a predetermined abnormality occurs, and then restarted after a predetermined period of time has elapsed. If an abnormality occurs even after performing the retry operation a predetermined number of times, the outdoor control unit 70 determines the abnormality as an official "abnormality."

Conventionally known methods can be applied to detect the abnormality. For example, regarding the compressor 30, if the current value flowing through the motor is higher than a predetermined threshold, or if the detected values of the suction pressure sensor 51 and the discharge pressure sensor 52 are higher or lower than the predetermined threshold, both pressure sensors 51, If the difference between the detected values of 52 and 52 is smaller than a predetermined threshold, it can be determined that there is an abnormality.

For example, the method shown in FIG. 5 can be applied to detect signs of abnormality. Details of FIG. 5 will be described later.

FIG. 3 is a configuration diagram of the outdoor control section.
The outdoor control section 70 includes a processing section 71, a storage section 72, a display section 73, and an output section 74. The processing unit 71 is constituted by an arithmetic unit such as a CPU, and performs processing for controlling the operation of the compressor 30 as described above, as well as processing for abnormality diagnosis.

When the processing unit 71 detects that an “abnormality”, “retry operation”, and “sign of an abnormality” have occurred, the processing unit 71 stores the information such as “abnormality information,” “retry information,” and “foreign information” in a storage unit. 72 is executed. The processing unit 71 executes a process of displaying the “abnormality information”, “retry information”, and “predictive information” stored in the storage unit 72 on the display unit 73. Further, the processing section 71 executes a process of displaying "abnormality information" among the various pieces of information stored in the storage section 72 on the display section 29A1 of the remote controller 29A. The processing unit 71 does not display the “predictive information” and the “retry information” on the display unit 29A1, but displays only the “abnormality information”.

The storage unit 72 stores detection data of various sensors of the air conditioner 11 and control data of the compressor 30 and the like. Furthermore, when the processing unit 71 detects the occurrence of “abnormality”, “retry operation”, and “predictive sign”, the storage unit 72 stores the “abnormality information”, “retry information”, and “predictive information”. Remember.

The "abnormality information" includes the details of the abnormality and information regarding the time of occurrence. The "foreshadowing information" includes the contents of the foreshadowing and information regarding the time of occurrence thereof. The "retry information" includes the details of the abnormality that caused the retry operation and information regarding the time at which the abnormality occurred.

FIG. 4 is a table illustrating the contents of abnormality information, retry information, and predictive information stored in the storage unit.
As shown in FIG. 4, the storage unit 72 stores the type of abnormality (abnormality, retry operation, sign), the content of the abnormality, and the cumulative energization time when the abnormality occurs (also simply referred to as "energization time"). ) and the cumulative compressor operating time when the abnormality occurs are stored in a correlated manner. The cumulative compressor operating time is substantially the operating time during which the air conditioner 11 performs air conditioning. In FIG. 4, "abnormality", "premonition", and "retry operation" are listed in order of occurrence from the bottom. The storage unit 72 can store the latest information and the past n pieces of information. For example, n can be 83 items, and a total of 84 pieces of information can be stored in the storage unit 72.

6A to 6C are tables illustrating the contents of abnormality information, retry information, and predictive information displayed on the display unit of the outdoor control unit.
The display unit 73 displays “abnormality information”, “retry information”, and “predictive information” stored in the storage unit 72. The display section 73 is, for example, a 7-segment digital display, and the abnormality information, retry information, and predictive information are displayed on the display section 73 in a coded state using numbers, alphabets, or the like. In this embodiment, the contents of the abnormality, the contents of the retry operation, and the contents of the sign are each coded as the abnormality information, retry information, and sign information, and are displayed on the display unit 73.

The display unit 73 displays three items of abnormality information, retry information, and predictive information, respectively, indicated as "latest", "past 1", and "past 2". Therefore, when the air conditioner 11 stops due to an abnormality, a service person or the like who is in charge of restoring it can view not only the details of the actual abnormality, but also information on recent retry operations and warning signs. The retry information and predictive information can be used to investigate the cause of the abnormality. However, the display unit 73 only displays three items of abnormality information, retry information, and predictive information, and it is difficult to grasp the relationship between them. Therefore, the outdoor control unit 70 of this embodiment is configured to output these pieces of information in a form that allows understanding of their mutual relationships.

As shown in FIG. 3, the output unit 74 of the outdoor control unit 70 outputs the abnormality information, retry information, and predictive information stored in the storage unit 72 to an external device such as a PC or smartphone owned by a service person. The data is output to the terminal 100 (hereinafter also referred to as "service terminal"). The output unit 74 is provided, for example, on a control board constituting the outdoor control unit 70, and includes an output interface or the like to which the service terminal 100 is connected by wire. The output unit 74 may be a communication device that wirelessly outputs abnormality information and the like.

As described above, the abnormality information, retry information, and predictive information stored in the storage unit 72 include the energization time and operation time of the air conditioner 11 at the time when each of them occurs, and the output unit 74 outputs the abnormality information, retry information, and predictive information to the outside, including information on the time of occurrence of these items. Therefore, for example, as shown in FIG. 4, it is possible to check abnormality information, retry information, and predictive information in chronological order. Therefore, the service person can confirm, based on the output information, what kind of retry operation was performed before the abnormality occurred or what kind of signs were present. Therefore, the service person can easily estimate the cause of the abnormality from the retry information and the predictive information, and can appropriately and quickly perform recovery from the abnormality (repair or replacement of parts).

The abnormality information, retry information, and sign information include the energization time and operating time of the air conditioner 11 as information regarding the time of occurrence. From this energization time, it can be determined whether the cause of the abnormality, retry operation, or sign of occurrence is due to wear and deterioration due to operation of the air conditioner 11. Similarly, it can be determined from the energization time whether the cause of abnormality, retry operation, or sign of occurrence is due to lifespan. Note that the output unit 74 may output the abnormality information, retry information, and predictive information to the display unit 73 of the outdoor control unit 70 in a state that can be checked in chronological order.

[Examples of signs of abnormality]
FIG. 5 is a table illustrating the contents of abnormality information, retry information, and predictive information stored in the storage unit.
FIG. 5 illustrates an example in which components constituting the air conditioner 11, contents of signs of an abnormality that may occur in the components, and methods for detecting the contents are associated with each other. For example, "current value,""wetness," and "overheating" are exemplified as the contents of signs of abnormality that may occur in the compressor 30.

"Current value" means that a state in which the current value flowing through the motor of the compressor 30 is higher than a predetermined value is detected. In this case, a moving average value from the current value to a predetermined period before is used as the current value, and an abnormality in the current value from a long-term perspective is detected. "Wetness" means that the wet state (degree of superheat is less than a predetermined value) of the refrigerant discharged by the compressor 30 is detected. “Superheating” means that an overheating state (the degree of superheating is equal to or higher than a predetermined value) of the refrigerant discharged by the compressor 30 is detected. When these conditions are detected, the outdoor control unit 70 diagnoses that the compressor 30 has a "sign of abnormality". However, even if these conditions are detected, the operation of the air conditioner 11 is not immediately affected, so the operation of the air conditioner 11 is continued.

In FIG. 5, "leak" is illustrated as a sign of an abnormality that may occur in the expansion valve 34. This means that the refrigerant temperature sensor located downstream of the expansion valve 34 detects the wet state of the refrigerant. When this state is detected, the outdoor control unit 70 diagnoses that the expansion valve 34 has a "sign of abnormality".

FIG. 5 shows "unmelted frost" as an example of a sign of abnormality that may occur in the outdoor heat exchanger 33. This means that when the air conditioner 11 is performing the defrost operation, the number of times the predetermined completion condition is not satisfied exceeds the predetermined number. When this state is detected, the outdoor control unit 70 diagnoses that the outdoor heat exchanger 33 has a "sign of abnormality". However, even if these conditions are detected, the operation of the air conditioner 11 is not immediately affected, so the operation of the air conditioner 11 is continued.

In FIG. 5, "detection deviation" is illustrated as a sign of abnormality in the temperature sensors 53 to 59. This means that a discrepancy in detected values is detected between the temperature sensor to be diagnosed and other temperature sensors. When this state is detected, the outdoor control unit 70 diagnoses that the temperature sensor has a "sign of abnormality".

FIG. 5 exemplifies "detection deviation" as a sign of abnormality in the pressure sensors 51 and 52. This means that a discrepancy is detected between the pressure-equivalent saturation temperature (calculated value) obtained from the detected values of the pressure sensors 51 and 52 to be diagnosed and the detected values of other temperature sensors. When this state is detected, the outdoor control unit 70 diagnoses that the pressure sensors 51 and 52 have a "sign of abnormality".

Even if the outdoor control unit 70 detects the occurrence of the above-mentioned signs, the operation of the air conditioner 11 will not be immediately affected, so the outdoor control unit 70 continues to operate the air conditioner 11 without stopping it. do. Among the signs of abnormality shown in FIG. 5, "current value" of the compressor 30, "leakage" of the expansion valve, "remaining frost melting" of the heat exchanger 33, "detection deviation" of the temperature sensors 53 to 59, and pressure sensor For the "detection deviations" 51 and 52, a method different from the method for detecting the occurrence of an abnormality is adopted so that a slight abnormality that does not require stopping the air conditioner 11 can be detected.

(Specific processing for detecting signs)
Among the above-mentioned "signs of abnormality", "detection deviation" between the temperature sensors 53 to 59 and the pressure sensors 51 and 52 will be explained in detail.
The various sensors installed in the air conditioner 11 may gradually deviate from the normal value (detection deviation), and if this detection deviation becomes large, the air conditioner 11 may not be properly controlled and may not operate properly. There is a risk of interference. Therefore, in the air conditioner 11 of this embodiment, if there is a "detection deviation" in the temperature sensors 53 to 59 and the pressure sensors 51, 52, it is diagnosed that there is a sign of abnormality.

Diagnosis of "detection deviation" of the temperature sensors 53 to 59 and pressure sensors 51, 52 is performed while the air conditioner 11 is stopped. The outdoor control unit 70 compares the detected values of each of the temperature sensors 53 to 59 and the calculated values obtained from each of the pressure sensors 51 and 52 with a predetermined reference value, and detects a state in which there is a large deviation from the reference value. If the detection continues for a predetermined period of time or more, the sensor is diagnosed as having a "detection error."

When the air conditioner 11 is stopped, the detected values of the temperature sensors 53 to 59 provided in the air conditioner 11 gradually converge to the outside air temperature. Further, the pressure equivalent saturation temperature determined from the detected values of the pressure sensors 51 and 52 provided in the air conditioner 11 gradually converges to the outside air temperature. In this embodiment, the outdoor control unit 70 sets a value corresponding to the outside air temperature as a "reference value", and uses this reference value, the detected values of the temperature sensors 53 to 59, and the detected values of the pressure sensors 51 and 52. "Detection deviation" is diagnosed by comparing the pressure-equivalent saturation temperature (calculated value) obtained from

FIG. 7 is a flowchart showing the procedure for diagnosing the detection deviation of the temperature sensor.
The procedure for diagnosing "detection deviation" of the temperature sensors 53 to 59 will be described below with reference to a flowchart.
In step S1, the outdoor control unit 70 determines whether the air conditioner 11 is stopped. If the determination in step S1 is affirmative (Yes), the outdoor control unit 70 advances the process to step S2.

The outdoor control unit 70 acquires the detection values of the temperature sensors 53 to 59 in step S2. Next, in step S3, the outdoor control unit 70 calculates a reference value using the detected values of the plurality of temperature sensors 53 to 59. In this embodiment, the reference value is the median value of any one of the detection values of the plurality of temperature sensors 53 to 59. Using the median value as the reference value reduces the possibility of being affected by abnormally high or low values detected by multiple temperature sensors, and increases the reproducibility of outside air temperature. This is because it is possible.

It is preferable that three or more temperature sensors are used to determine the reference value. If there is an even number of temperature sensors used to obtain the reference value, the average value of two values close to the median value can be adopted as the reference value. In this embodiment, the temperature sensors 54 and 59 disposed around the compressor 30 are easily affected by the heat of the compressor 30, and therefore are not used for calculating the reference value.

In step S4, the outdoor control unit 70 determines whether the difference between the detection value of each temperature sensor 53 to 58 and the reference value exceeds a predetermined threshold value. If the determination in step S4 is affirmative (Yes), the outdoor control unit 70 determines in step S5 whether a predetermined period of time has elapsed after the air conditioner 11 was stopped. This predetermined time can be, for example, 8 hours. If the determination in step S5 is affirmative (Yes), the outdoor control unit 70 diagnoses that a “detection deviation” has occurred in the temperature sensors 53 to 59, and stores it in the storage unit 72 as abnormality sign information. and ends the process.

If the determination in step S4 is negative (No), the outdoor control unit 70 advances the process to step S8, diagnoses that there is no "detection deviation" in the temperature sensors 53 to 59, and ends the process. .

The predetermined threshold value used in step S4 can be set depending on the type of temperature sensor to be diagnosed. For example, since the compressor 30 is warmed by the crankcase heater while the air conditioner 11 is stopped, the temperature sensors 54 and 59 disposed around the compressor 30 detect more temperature than the other temperature sensors 53 and 55 to 58. The value becomes higher. Therefore, the predetermined threshold values for these temperature sensors 54 and 59 are set relatively high.

The reason why the time for diagnosing "detection deviation" is set to a long time of 8 hours is because it takes a certain amount of time for the detected value of the temperature sensor to converge to the ambient temperature (outside temperature). However, this time is not particularly limited.

FIG. 8 is a flowchart showing a procedure for diagnosing detection deviation of the pressure sensor.
Hereinafter, a procedure for diagnosing "detection deviation" of the pressure sensors 51 and 52 will be explained with reference to a flowchart.
In step S11, the outdoor control unit 70 determines whether the air conditioner 11 is stopped. If the determination in step S1 is affirmative (Yes), the outdoor control unit 70 advances the process to step S12.

In step S12, the outdoor control unit 70 acquires the detection values of the pressure sensors 51, 52 and the temperature sensors 53 to 59. Next, in step S13, the outdoor control unit 70 calculates a reference value using any one of the detection values of the plurality of temperature sensors 53 to 59. In this embodiment, the median value of the plurality of detected values is used as the reference value. Using the median value as the reference value reduces the influence of abnormally high or low values detected by multiple temperature sensors, and improves the reproducibility of outside air temperature. This is because it can be improved.

It is preferable that three or more temperature sensors are used to determine the reference value. If there is an even number of temperature sensors used to determine the reference value, the average value of two values near the center can be adopted as the reference value. Since the temperature sensors 54 and 59 arranged around the compressor 30 are easily affected by the heat of the compressor 30, it is preferable not to use them for calculating the reference value.

In step S14, the outdoor control unit 70 uses the detected values of the pressure sensors 51 and 52 to calculate the pressure-equivalent saturation temperature of the refrigerant. Then, in step S15, the outdoor control unit 70 determines whether the difference between the pressure-equivalent saturation temperature obtained from the detection values of the pressure sensors 51 and 52 and the reference value exceeds a predetermined threshold value. If the determination in step S15 is affirmative, the outdoor control unit 70 determines in step S16 whether a predetermined time has elapsed since the air conditioner 11 stopped. This predetermined time can be, for example, 8 hours. If the determination in step S16 is affirmative (Yes), the outdoor control unit 70 diagnoses that a "detection deviation" has occurred in the pressure sensors 51 and 52 (step S17), and stores it as abnormality sign information. 72 (step S18), and the process ends.

If the determination in step S15 is negative (No), the outdoor control unit 70 advances the process to step S19, diagnoses that there is no "detection deviation" in the pressure sensors 51 and 52, and ends the process. .

[Other embodiments]
In the above embodiment, the reference value calculated in step S3 of FIG. 7 and step S13 of FIG. 8 is not limited to the median value of the detection values of the plurality of temperature sensors, but may be an average value. In this case, it is more preferable to calculate the average value using detected values other than the maximum value and minimum value among the plurality of detected values.

In the flowcharts shown in FIGS. 7 and 8, the temperature sensor for calculating the reference value may use a detected value of a temperature sensor that is not a diagnostic target. Since the air conditioner 11 is provided with a temperature sensor 58 that detects the temperature of the outside air, the detected value of the temperature sensor 58 can also be used as a reference value. However, in this case, if a "detection shift" occurs in the temperature sensor 58 itself, the detection shifts of the other temperature sensors 51 to 57, 59 cannot be detected, so the center of the detected values of the multiple temperature sensors It is more preferable to set the reference value using a value or an average value.

When the processing unit 71 in the outdoor control unit 70 diagnoses that there is a “detection deviation” in the temperature sensors 53 to 59 and the pressure sensors 51 and 52, the processing unit 71 calculates the detected value from the detected value of the temperature sensor or the detected value of the pressure sensor. A correction value may be determined according to the difference between the calculated value (pressure equivalent saturation temperature) and the reference value, and the operation of the air conditioner 11 may be controlled using this correction value.

The processing unit 71 in the outdoor control unit 70 may transmit the results of the abnormality diagnosis to the central management device 50, and the central management device 50 may manage the abnormality information, retry information, and predictive information. Further, the processing unit 71 in the outdoor control unit 70 may transmit the results of the abnormality diagnosis to the management server 62, and the management server 62 may manage the results of the abnormality diagnosis. By transmitting only the results of the abnormality diagnosis instead of the operation data of the air conditioner 11, it is possible to suppress an increase in communication traffic. When managing the results of abnormality diagnosis in the management server 62, in order to eliminate the inconvenience that the outdoor control unit 70 cannot refer to the abnormality information, retry information, and predictive information, the management server 62 manages the abnormality information, retry information, and predictive information. It is more preferable to include a transmitter that transmits information to the service terminal 100, the central management device 50, etc. via the wide area communication network 63.

In the embodiment described above, the air conditioner 11 is provided with an abnormality diagnosis system (outdoor control unit 70), but the central management device 50 may be provided with an abnormality diagnosis system. In this case, the operation data of the air conditioner 11 is transmitted from the air conditioner 11 to the central management device 50, and the abnormality is diagnosed in the control unit 50a of the central management device 50. However, operating data is only sent from the air conditioner 11 to the central control device 50 at predetermined intervals, which limits the amount of operating data that can be used for abnormality diagnosis. In this regard, it is more preferable that the air conditioner 11 is provided with an abnormality diagnosis system.

Similarly, the management server 62 may be provided with an abnormality diagnosis system. In this case, the operation data of the air conditioner 11 is transmitted from the central management device 50 or the air conditioner 11 to the management server 62, and the control unit 62a of the management server 62 diagnoses the abnormality. In this case, it is necessary to transmit a large amount of operation data of the air conditioner 11 to the management server 62 via the wide area communication network 63, resulting in a large communication cost. Therefore, it is more preferable that the air conditioner 11 or the central control device 50 is provided with an abnormality diagnosis system.

Note that when managing the results of abnormality diagnosis in the management server 62, in order to eliminate the inconvenience that the outdoor control unit 70 and the central management device 50 cannot refer to abnormality information, retry information, and predictive information, the management server 62 manages abnormality diagnosis results. It is more preferable to include a transmitter that transmits information, retry information, and predictive information to the service terminal 100, the central management device 50, etc. via the wide area communication network 63.

In the above embodiment, the processing section 71, the storage section 72, and the output section 74 that constitute the abnormality diagnosis system are all integrated into one device (the outdoor control section 70 of the air conditioner 11, the control section 50a of the central management device 50, Alternatively, these are provided in the control unit 62a) of the management server 62, but these may be provided in separate devices, for example, different control units (computers), and these different control units cooperate with each other to prevent abnormalities. A diagnostic system may be configured.

In the embodiment described above, the plurality of temperature sensors 53 to 59 and the plurality of pressure sensors 51 and 52 are subject to diagnosis of "detection deviation", but at least one sensor among them is subject to diagnosis of detection deviation. It is fine as long as it is.

[Operations and effects of embodiment]
(1) In the above embodiment, the outdoor control unit (diagnosis system) 70 acquires the detected values of the sensors 51 to 59 provided in the air conditioner 11 while the air conditioner 11 is stopped, and A processing unit 71 is provided that diagnoses the detection states of the sensors 51 to 59 based on a calculated value (for example, pressure equivalent saturation temperature) obtained from the detected values. While the air conditioner 11 is stopped, the detected values of the sensors 51 to 59 provided in the air conditioner 11 converge to a certain value depending on the surrounding environment, for example, the outside air temperature or a value corresponding to the outside air temperature. It is thought that this will continue. In the present disclosure, the detected values of the sensors 51 to 59 to be diagnosed are acquired while the air conditioner 11 is stopped, and the detected values or the calculated values obtained from the detected values are combined with the value ( By comparing with the standard value), it is possible to understand how much deviation the sensors 51 to 59 have from the normal state, and the detection status of the sensors 51 to 59 can be determined from the magnitude of the deviation. can be diagnosed.

(2) In the above embodiment, the sensors 51-59 are temperature sensors 53-59. The processing unit 71 diagnoses the detection state based on a comparison between the detection value and a predetermined reference value. The reference value is obtained from the detection values of a plurality of temperature sensors 53, 55 to 58 provided in the air conditioner 11. In this way, by determining the reference value from the detected values of the temperature sensors 53, 55 to 58 provided in the air conditioner 11, an appropriate reference value can be set according to the surrounding environment of the installation location of the air conditioner 11. can do.

(3) In the above embodiment, the reference value is the median value of the values detected by the plurality of temperature sensors 53, 55 to 58 provided in the air conditioner 11. In this way, by using the median value of the detected values of the plurality of temperature sensors 53, 55 to 58 as the reference value, if the detected values include an abnormal value, that value will have a negative impact on the reference value. can be suppressed.

(4) In the other embodiments described above, the reference value is the average value of the detection values of the plurality of temperature sensors 53, 55 to 58 provided in the air conditioner 11. In this case, the average value is obtained by omitting the maximum value and minimum value of the detected values of the plurality of temperature sensors 53, 55-58. Thereby, even if the detected values of the plurality of temperature sensors 53, 55 to 58 include abnormally large or small values, it is possible to prevent the values from having an adverse effect on the reference value.

(5) In the above embodiment, the reference value is determined using the detected values of the sensors 53 to 58 to be diagnosed. Further, in the other embodiments described above, the reference value is the detection value of the outside air temperature sensor (ambient temperature sensor) 58 that detects the air temperature around the air conditioner 11, and the sensor to be diagnosed is the ambient temperature sensor. These are temperature sensors 53 to 57 and 59 other than 58. By using the detected value of the ambient temperature sensor 58 as a reference value, calculations such as a median value and an average value are not necessary, and the processing of the processing unit 71 can be reduced.

(6) In the above embodiment, the sensors to be diagnosed are the pressure sensors 51 and 52 that detect the pressure of the refrigerant. While the air conditioner 11 is stopped, the detected values of the pressure sensors 51 and 52 provided in the air conditioner 11 converge to a value corresponding to the surrounding environment. Therefore, by comparing the detected values of the pressure sensors 51, 52 or the calculated values obtained from the detected fixed values with a reference value depending on the surrounding environment, it is possible to determine the degree of detection deviation of the pressure sensors 51, 52 from the normal state. You can figure out what you have.

(7) In the above embodiment, the processing unit 71 of the outdoor control unit (diagnosis system) 70 determines the pressure-equivalent saturation temperature from the detected values of the pressure sensors 51 and 52 as a calculated value to be compared with a reference value. Therefore, the detection deviation of the pressure sensors 51 and 52 can be diagnosed by comparing the temperature with a reference value.

(8) In the other embodiments described above, when the difference between the detection value of the sensors 51 to 59 or the calculated value obtained from the detection value and the reference value exceeds a predetermined threshold value, the processing unit 71 A corresponding correction value is determined, and the operation of the air conditioner 11 is controlled based on the correction value. Thereby, even if there is a detection error in the sensor, operation of the air conditioner 11 can be continued as an emergency measure.

Note that the present disclosure is not limited to the above examples, but is indicated by the scope of the claims, and is intended to include all changes within the meaning and scope equivalent to the scope of the claims.

11: Air conditioner 50: Centralized control device (first control device)
50a: Control unit (diagnosis system)
51: Pressure sensor 52: Pressure sensor 53: Temperature sensor 54: Temperature sensor 55: Temperature sensor 56: Temperature sensor 57: Temperature sensor 58: Temperature sensor (ambient temperature sensor)
59: Temperature sensor 62: Management server 62a: Control unit (diagnosis system)
70: Outdoor control unit (diagnosis system)
71: Processing section 72: Storage section 73: Display section 74: Output section

Claims (11)

While the air conditioner (11) is stopped, the detected values of the sensors (51 to 59) provided in the air conditioner (11) are acquired, and based on the detected values or the calculated values obtained from the detected values, A diagnostic system comprising a processing unit (71) that diagnoses the detection state of the sensors (51 to 59),
Some of the sensors (51, 52) are pressure sensors that detect the pressure of the refrigerant,
The processing unit (71) obtains a pressure equivalent saturation temperature as the calculated value from the detected values of some of the sensors (51, 52),
The processing unit (71) diagnoses the detection state based on a comparison between the calculated value and a predetermined reference value, and the reference value is determined by the sensor (51 to 51) provided in the air conditioner (11). The diagnostic system is determined only from the detected values of a plurality of temperature sensors (53, 55 to 58), which are some of the other sensors of 59), and is the median value of the detected values. While the air conditioner (11) is stopped, the detected values of the sensors (51 to 59) provided in the air conditioner (11) are acquired, and based on the detected values or the calculated values obtained from the detected values, A diagnostic system comprising a processing unit (71) that diagnoses the detection state of the sensors (51 to 59),
Some of the sensors (51, 52) are pressure sensors that detect the pressure of the refrigerant,
The processing unit (71) obtains a pressure equivalent saturation temperature as the calculated value from the detected values of some of the sensors (51, 52),
The processing unit (71) diagnoses the detection state based on a comparison between the calculated value and a predetermined reference value, and the reference value is determined by the sensor (51 to 51) provided in the air conditioner (11). 59) A diagnostic system that is obtained only from the detected values of a plurality of temperature sensors (53, 55 to 58), which are some of the other sensors of 59), and is an average value of the detected values. The diagnosis according to claim 2, wherein the average value is obtained by omitting a maximum value and a minimum value among the detection values of a plurality of temperature sensors (53, 55 to 58) that are some of the other sensors. system. When the difference between the calculated value and the reference value exceeds a threshold, the processing unit (71) calculates a correction value according to the difference, and uses the correction value in the air conditioner (11). The diagnostic system according to any one of claims 1 to 3, which instructs operational control. An air conditioner comprising the diagnostic system according to any one of claims 1 to 4. a step of acquiring detection values of sensors (51 to 59) provided in the air conditioner (11) while the air conditioner (11) is stopped;
A diagnostic method comprising the step of diagnosing the detection state of the sensor (51 to 59) based on the detected value or a calculated value obtained from the detected value,
Some of the sensors (51, 52) are pressure sensors that detect the pressure of the refrigerant,
Determining a pressure equivalent saturation temperature as the calculated value from the detected values of some of the sensors (51, 52),
The detected state is diagnosed based on a comparison between the calculated value and a predetermined reference value, and the reference value is determined by another part of the sensors (51 to 59) provided in the air conditioner (11). A diagnostic method that is determined only from the detected values of a plurality of temperature sensors (53, 55 to 58), and the median value of the detected values. a step of acquiring detection values of sensors (51 to 59) provided in the air conditioner (11) while the air conditioner (11) is stopped;
A diagnostic method comprising the step of diagnosing the detection state of the sensor (51 to 59) based on the detected value or a calculated value obtained from the detected value,
Some of the sensors (51, 52) are pressure sensors that detect the pressure of the refrigerant,
Determining a pressure equivalent saturation temperature as the calculated value from the detected values of some of the sensors (51, 52),
The detected state is diagnosed based on a comparison between the calculated value and a predetermined reference value, and the reference value is determined by another part of the sensors (51 to 59) provided in the air conditioner (11). A diagnostic method that is determined only from detected values of a plurality of temperature sensors (53, 55 to 58), and is an average value of the detected values. The diagnosis according to claim 7, wherein the average value is obtained by omitting a maximum value and a minimum value among the detection values of a plurality of temperature sensors (53, 55 to 58) that are some of the other sensors. Method. A procedure for acquiring detection values of sensors (51 to 59) provided in the air conditioner (11) while the air conditioner (11) is stopped;
A diagnostic program that causes a computer to execute a procedure for diagnosing the detection state of the sensor (51 to 59) based on the detected value or a calculated value obtained from the detected value,
Some of the sensors (51, 52) are pressure sensors that detect the pressure of the refrigerant,
Determining a pressure equivalent saturation temperature as the calculated value from the detected values of some of the sensors (51, 52),
The detected state is diagnosed based on a comparison between the calculated value and a predetermined reference value, and the reference value is determined by another part of the sensors (51 to 59) provided in the air conditioner (11). A diagnostic program in which the median value of the detected values is obtained only from the detected values of a plurality of temperature sensors (53, 55 to 58). A procedure for acquiring detection values of sensors (51 to 59) provided in the air conditioner (11) while the air conditioner (11) is stopped;
A diagnostic program that causes a computer to execute a procedure for diagnosing the detection state of the sensor (51 to 59) based on the detected value or a calculated value obtained from the detected value,
Some of the sensors (51, 52) are pressure sensors that detect the pressure of the refrigerant,
Determining a pressure equivalent saturation temperature as the calculated value from the detected values of some of the sensors (51, 52),
The detected state is diagnosed based on a comparison between the calculated value and a predetermined reference value, and the reference value is determined by another part of the sensors (51 to 59) provided in the air conditioner (11). A diagnostic program that is an average value of the detected values obtained only from the detected values of a plurality of temperature sensors (53, 55 to 58). The diagnosis according to claim 10, wherein the average value is obtained by omitting a maximum value and a minimum value among the detection values of a plurality of temperature sensors (53, 55 to 58) that are some of the other sensors. program.

Images