JP2024036955A - Management system, management method, information processing device, program, and refrigeration cycle device - Google Patents

Abstract

The present disclosure provides a management system that supports inspection of an infrared refrigerant leak sensor provided in a refrigeration cycle device depending on whether or not it has a self-diagnosis function. [Solution] A management system in the present disclosure includes a refrigeration cycle device equipped with an infrared refrigerant leak sensor and an information processing device, and the refrigeration cycle device includes a refrigerant leak sensor equipped with a self-diagnosis function. The information processing device sends self-diagnosis function information indicating whether the refrigerant leak sensor is equipped with a self-diagnosis function based on the self-diagnosis function information, and When the refrigerant leak sensor is equipped with a self-diagnosis function, it receives self-diagnosis result information indicating the diagnosis result from the self-diagnosis function from the refrigeration cycle equipment, and notifies the self-diagnosis result information. If the refrigerant leakage sensor is not checked, it will notify you when it is time to check the refrigerant leakage sensor. [Selection diagram] Figure 1

Description

The present disclosure relates to a management system, a management method, an information processing device, a program, and a refrigeration cycle device for a refrigeration cycle device.

Patent Document 1 discloses a configuration in which an infrared refrigerant leak sensor is used as a sensor for detecting refrigerant leak in an air conditioner that is an example of a refrigeration cycle device using a slightly flammable refrigerant.

Patent No. 6402779 specification

The present disclosure provides a management system that supports inspection of an infrared refrigerant leak sensor provided in a refrigeration cycle device depending on whether or not it has a self-diagnosis function.

A management system according to the present disclosure includes a refrigeration cycle device equipped with an infrared refrigerant leak sensor that detects refrigerant leakage, and an information processing device, and includes a refrigeration cycle device and an information processing device. In the management system that communicates, the refrigeration cycle device transmits self-diagnosis function information indicating whether or not the refrigerant leak sensor is equipped with a self-diagnosis function for diagnosing the operating status of the refrigerant leak sensor. the information processing device determines whether or not the refrigerant leak sensor is equipped with the self-diagnosis function based on the self-diagnosis function information, and the information processing device determines whether the refrigerant leak sensor is equipped with the self-diagnosis function. is provided, the self-diagnosis result information indicating the diagnosis result by the self-diagnosis function is received from the refrigeration cycle device and the self-diagnosis result information is notified, and the self-diagnosis function is provided to the refrigerant leak sensor. If the refrigerant leakage sensor is not provided, the time to inspect the refrigerant leakage sensor is notified.

A management method in the present disclosure includes a refrigeration cycle device equipped with an infrared refrigerant leak sensor that detects refrigerant leakage, and an information processing device, and a management method that includes a refrigeration cycle device and an information processing device. A management method executed by a management system that communicates with the refrigerant cycle apparatus, wherein the refrigerant cycle apparatus includes a self-diagnosis function that indicates whether or not the refrigerant leakage sensor is equipped with a self-diagnosis function that diagnoses the operating status of the refrigerant leakage sensor. transmitting diagnostic function information to the information processing device; the information processing device determining whether the refrigerant leak sensor is equipped with the self-diagnosis function based on the self-diagnosis function information; When the refrigerant leak sensor is equipped with the self-diagnosis function, the self-diagnosis result information indicating the diagnosis result by the self-diagnosis function is received from the refrigeration cycle device and the self-diagnosis result information is notified; When the refrigerant leak sensor is not equipped with the self-diagnosis function, the method includes the step of notifying the inspection timing of the refrigerant leak sensor.

An information processing device according to the present disclosure includes a communication control unit that communicates with a refrigeration cycle device that is equipped with an infrared refrigerant leak sensor that detects refrigerant leakage, and a communication control unit that communicates with a refrigeration cycle device that transmits the refrigerant from the refrigeration cycle device. a self-diagnosis function information acquisition unit that receives and acquires self-diagnosis function information indicating whether or not the leak sensor is equipped with a self-diagnosis function for diagnosing the operating status of the refrigerant leak sensor; Based on the self-diagnosis function information, it is determined whether or not the refrigerant leak sensor is equipped with the self-diagnosis function, and when the refrigerant leak sensor is equipped with the self-diagnosis function, the self-diagnosis function is used. The communication control unit receives self-diagnosis result information indicating the diagnosis result from the refrigeration cycle device and notifies the self-diagnosis result information, and when the refrigerant leak sensor is not equipped with the self-diagnosis function, the refrigerant A sensor information notification unit that notifies the inspection timing of the leakage sensor.

A program according to the present disclosure includes a communication control unit that communicates between a computer and a refrigeration cycle device that is equipped with an infrared refrigerant leak sensor that detects refrigerant leakage, and a communication control unit that communicates with a refrigeration cycle device that transmits information from the refrigeration cycle device. a self-diagnosis function information acquisition unit that receives and acquires self-diagnosis function information indicating whether or not the refrigerant leak sensor is equipped with a self-diagnosis function for diagnosing the operating status of the refrigerant leak sensor; Based on the self-diagnosis function information, it is determined whether or not the refrigerant leak sensor is equipped with the self-diagnosis function, and when the refrigerant leak sensor is equipped with the self-diagnosis function, the self-diagnosis function is The communication control unit receives self-diagnosis result information indicating a diagnosis result from the refrigeration cycle device and notifies the self-diagnosis result information, and when the refrigerant leak sensor is not equipped with the self-diagnosis function, It functions as a sensor information notification unit that notifies the inspection timing of the refrigerant leak sensor.

A refrigeration cycle device according to the present disclosure includes a refrigeration cycle through which a refrigerant flows, an infrared refrigerant leak sensor that detects leakage of the refrigerant, a communication control unit that communicates with an external device, and a communication control unit that communicates with an external device. , a self-diagnosis function information providing unit that transmits self-diagnosis function information indicating whether or not a self-diagnosis function for diagnosing the operating status of the refrigerant leak sensor is provided to the external device by the communication control unit. .

The management system according to the present disclosure can manage the infrared refrigerant leakage sensors provided in the refrigeration cycle device, depending on whether the refrigerant leakage sensor has a self-diagnosis function or not. Therefore, it is possible to reduce the frequency of inspections of refrigerant leak sensors that have a self-diagnosis function, and to encourage periodic inspections of refrigerant leak sensors that do not have a self-diagnosis function. Appropriate use can be managed.

Configuration diagram of management system in embodiment Configuration diagram of a refrigerant leak sensor in an embodiment Configuration diagram of an air conditioner in an embodiment Configuration diagram of an information processing device in an embodiment First flowchart of the information processing device in the embodiment Second flowchart of the information processing device in the embodiment Flowchart of air conditioner in embodiment

(Findings, etc. that formed the basis of this disclosure)
At the time the inventors came up with the present disclosure, semiconductor-type refrigerant leak sensors and infrared-type refrigerant leak sensors were known as refrigerant leak sensors that are included in refrigeration cycle devices and detect refrigerant leaks. Ta. Semiconductor-type refrigerant leak sensors are susceptible to aging because their sensor elements easily react with outside air, and require periodic replacement, whereas infrared-type refrigerant leak sensors are susceptible to aging. It has the advantage of being difficult.

Therefore, by employing an infrared refrigerant leak sensor as the refrigerant leak sensor, there is an advantage that maintenance of the refrigerant leak sensor becomes easier than when a semiconductor refrigerant leak sensor is employed. However, due to the characteristic of infrared refrigerant leak sensors that they are not easily affected by aging, there is a risk that maintenance of infrared refrigerant leak sensors may be neglected, resulting in delays in responding to refrigerant leak sensor malfunctions, etc. The inventors discovered that there is a problem, and in order to solve the problem, they have come to form the subject matter of the present disclosure.
Therefore, the present disclosure makes it possible to reduce the frequency of inspections for refrigerant leak sensors that have a self-diagnosis function, and to encourage regular inspections for refrigerant leak sensors that do not have a self-diagnosis function. A management system is provided that supports proper use of refrigerant leak sensors.

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

(Embodiment)
Embodiments will be described below using FIGS. 1 to 7.
[1. Management system configuration]
The configuration of a management system 1 in the present disclosure will be described with reference to FIG. 1. The management system 1 includes an air conditioner 10 and an information processing device 100. The air conditioner 10 and the information processing device 100 communicate with each other via the communication network 300. Further, the information processing device 100 communicates with a terminal device 200 used by an administrator P who manages the operation of the air conditioner 10 via the communication network 300. The air conditioner 10 is an example of a refrigeration cycle device of the present disclosure. The refrigeration cycle device of the present disclosure may be a refrigerator, a showcase, etc. equipped with an infrared refrigerant leak sensor.

The air conditioner 10 includes one outdoor unit 20 and three indoor units 50 (50a, 50b, 50c) connected in parallel to the outdoor unit 20 through a refrigerant pipe 11. In the air conditioner 10, a refrigeration cycle 30 is configured by an outdoor unit 20, an indoor unit 50, and a refrigerant pipe 11. The air conditioner 10 air-conditions a room in which the indoor unit 50 is installed by circulating refrigerant compressed by the outdoor unit 20 between the outdoor unit 20 and the indoor unit 50 via the refrigerant piping 11. . In this embodiment, a case where a flammable refrigerant is used as the refrigerant will be exemplified. The flammable refrigerant is R32 or a mixed refrigerant containing 70% by weight or more of R32, or propane or a mixed refrigerant containing propane. Note that the refrigerant used in the air conditioner 10 is not limited to a flammable refrigerant, and may be a nonflammable refrigerant.

The outdoor unit 20 includes a compressor 31 , a gas-liquid separator 32 , an oil separator 33 , a four-way valve 34 , an outdoor heat exchanger 36 having an outdoor blower fan 35 , and an outdoor expansion valve 37 . A gas-liquid separator 32 that supplies gas refrigerant to the compressor 31 is connected to the suction side of the compressor 31, and a four-way valve 34 is connected to the discharge side of the compressor 31 via an oil separator 33. ing. An outdoor heat exchanger 36 is connected to the four-way valve 34 . In the outdoor heat exchanger 36 , heat exchange is performed between the air sent by the outdoor fan 35 and the refrigerant flowing through the outdoor heat exchanger 36 . An outdoor expansion valve 37 is connected to the outdoor heat exchanger 36 .

The outdoor unit 20 includes an outdoor unit control unit 22 that controls the operation of the outdoor unit 20, and controls the compressor 31, the four-way valve 34, the outdoor blower fan 35, and the outdoor unit according to a control signal output from the outdoor unit control unit 22. The operation of the expansion valve 37 and the like is controlled. Furthermore, the outdoor unit control unit 22 is connected to an indoor unit control unit 52 that is included in each indoor unit 50 and controls the operation of the indoor unit 50 via a communication line 12, and is connected to an indoor unit control unit 52 that is provided in each indoor unit 50 and controls the operation of the indoor unit 50. communicate with each other. A plurality of indoor units 50 are connected to the outdoor expansion valve 37 and the four-way valve 34 via refrigerant pipes 11.

Each indoor unit 50 includes an indoor heat exchanger 81 equipped with an indoor ventilation fan 80, an indoor expansion valve 82, a temperature sensor 83 that detects the temperature of the room where the indoor unit 50 is installed, and a temperature sensor 83 that detects the temperature of the room where the indoor unit 50 is installed. It is equipped with a humidity sensor 84 that detects humidity and a refrigerant leak sensor 85 that detects refrigerant leakage.

The indoor expansion valve 82 has one end connected to the indoor heat exchanger 81 and the other end connected to the refrigerant pipe 11. A first on-off valve 13 and a second on-off valve 15 that adjust the flow rate of refrigerant supplied from the refrigerant pipe 11 to the indoor unit 50 are provided on both sides of the indoor heat exchanger 81. The first on-off valve 13 is provided in the liquid side pipe 14 connected to the indoor heat exchanger 81. The first on-off valve 13 can be switched between an open state where refrigerant flows and a closed state where refrigerant flow is blocked. Note that the first on-off valve 13 may be an opening adjustment valve that can be set between an open state and a closed state. The second on-off valve 15 is provided in a gas side pipe 16 connected to the indoor heat exchanger 81. The configuration of the second on-off valve 15 is similar to that of the first on-off valve 13.

The operation of the first on-off valve 13, the second on-off valve 15, the indoor ventilation fan 80, etc. is controlled by the control signal output from the indoor unit control unit 52. Detection signals from a temperature sensor 83, a humidity sensor 84, and a refrigerant leak sensor 85 are input to the indoor unit control unit 52. The indoor unit control unit 52 recognizes the temperature, humidity, and presence or absence of refrigerant leakage in the room in which the indoor unit 50 is installed based on detection signals from the temperature sensor 83, humidity sensor 84, and refrigerant leakage sensor 85.

The outdoor unit control unit 22 recognizes the temperature and humidity of the room in which the indoor unit 50 is installed, the presence or absence of refrigerant leakage, the operating status of the indoor unit 50, etc. through communication with the indoor unit control unit 52. The outdoor unit control unit 22 transmits operating status information indicating the operating status of the air conditioner 10 and sensor information indicating the specifications and operating status of the refrigerant leak sensor 85 to the information processing apparatus 100 via the communication network 300.

The information processing device 100 records the driving status information received from the outdoor unit control unit 22 in a driving status DB (database) 123, and records the sensor information received from the outdoor unit control unit 22 in the sensor information DB 122. The information processing device 100 transmits driving status information, sensor information, sensor inspection information for prompting inspection of the refrigerant leak sensor 85, etc. to the terminal device 200, and displays this information on the display unit of the terminal device 200. In this way, by displaying this information on the display section of the air conditioner 10, maintenance of the refrigerant leak sensor 85 provided in the air conditioner 10 by the administrator P is supported.

The process in which the information processing apparatus 100 transmits information to the terminal device 200 and causes the display unit of the terminal 200 to display the information corresponds to the notification of information in the present disclosure. Note that the information disclosed herein may be broadcast by sending information from the information processing device 100 via email to the terminal 200 or a mobile terminal (smartphone, mobile phone, tablet terminal, etc.) used by the administrator P. It also includes transmitting information by other methods.

[2. Configuration of refrigerant leak sensor]
With reference to FIG. 2, the configuration of the refrigerant leak sensor 85 provided in the indoor unit 50 will be described. FIG. 2 shows the configuration of a refrigerant leak sensor 85 having a self-diagnosis function. The refrigerant leak sensor 85 is of an infrared type and includes a light emitting section 90 that emits infrared light, and a first light receiving section 91 and a second light receiving section 92 that receive the infrared light emitted from the light emitting section 90. The light emitting section 90, the first light receiving section 91, and the second light receiving section 92 are provided facing each other, and the first light receiving section 91 is provided with an optical filter 93.

The optical filter 93 has a light blocking property outside the infrared absorption wavelength range of the refrigerant, and has a property of blocking a part of the infrared rays (light of the wavelength to be blocked) irradiated from the light emitting section 90. The refrigerant leak sensor 85 includes a leak detector 94 that detects refrigerant leakage based on the output of the first light receiver 91, and a refrigerant leak sensor due to disturbance based on the outputs of the first light receiver 91 and the second light receiver 92. A self-diagnosis section 95 is provided to detect malfunction of the 85. The disturbance includes dew condensation and dust accumulation between the light emitting section 90 and the first light receiving section 91 and the second light receiving section 92, a decrease in power supply for operating the refrigerant leak sensor 85, and the like.

When dew condensation or dust accumulates between the light emitting section 90 and the first light receiving section 91 and the second light receiving section 92, the infrared rays emitted from the light emitting section 90 are blocked by the condensation and dust, and the first light receiving section 91 The amount of light received by the second light receiving section 92 decreases, and the outputs of the first light receiving section 91 and the second light receiving section 92 decrease. Therefore, when the outputs of the first light receiving section 91 and the second light receiving section 92 are both below the determination level, the self-diagnosis section 95 sends a sensor error signal indicating that the refrigerant leak sensor 85 is malfunctioning. Output SEr.

When the refrigerant leakage sensor 85 is operating normally, when refrigerant leaks, the output of the first light receiving section 91 is greatly reduced due to the action of the optical filter 93 . On the other hand, since the second light receiving section 92 is not provided with the optical filter 93, the output decreases only slightly. Therefore, the leak detection section 94 outputs a leak detection signal Lk_ON indicating that a refrigerant leak has occurred when the output of the first light receiving section 91 becomes equal to or lower than a predetermined leak detection level.

In a refrigerant leak sensor that does not have a self-diagnosis function, the second light receiving section 92 and self-diagnosis section 95 are omitted from the configuration shown in FIG. 2, and the sensor error signal SEr is not output.

[3. Configuration of air conditioner]
The configuration of the control system of the air conditioner 10 will be described with reference to FIG. 3. In FIG. 3, for convenience of explanation, only one of the three indoor units 50 (50a, 50b, 50c) shown in FIG. 1 is shown. The configuration and operation of each indoor unit 50 are similar. The outdoor unit 20 includes the above-mentioned outdoor unit control unit 22 and an outdoor unit communication circuit 21. The outdoor unit communication circuit 21 communicates with the information processing device 100 via the communication network 300 and communicates with the indoor unit 50 via the communication line 12.

The outdoor unit control unit 22 includes an outdoor unit processor 40, an outdoor unit memory 45, etc., and an outdoor unit program 46 for controlling the outdoor unit 20 is stored in the outdoor unit memory 45. The outdoor unit processor 40 functions as an outdoor unit communication control section 41, a self-diagnosis function information provision section 42, a self-diagnosis result information provision section 43, and an operation information provision section 44 by reading and executing the outdoor unit program 46. .

The outdoor unit communication control unit 41 controls communication between the information processing device 100 and the indoor unit 50 by the outdoor unit communication circuit 21. In this case, the information processing device 100 corresponds to an external device of the present disclosure. The self-diagnosis function information providing unit 42 transmits self-diagnosis function information indicating whether the refrigerant leak sensor 85 provided in the indoor unit 50 has a self-diagnosis function to the information processing device 100. The self-diagnosis function information providing unit 42 recognizes whether the refrigerant leak sensor 85 has a self-diagnosis function based on the specification information of the refrigerant leak sensor 85 transmitted from the indoor unit 50.

The self-diagnosis result information providing unit 43 transmits self-diagnosis function result information indicating the diagnosis status by the self-diagnosis function of the refrigerant leak sensor 85 to the information processing device 100. The self-diagnosis result information providing unit 43 recognizes the diagnosis status by the self-diagnosis function of the refrigerant leak sensor 85 based on the output information of the sensor error signal SEr of the refrigerant leak sensor 85 transmitted from the indoor unit 50.

The operating information providing unit 44 transmits operating status information indicating the operating status of the outdoor unit 20 and indoor unit 50 and refrigerant detection information indicating the detection status of refrigerant leakage by the refrigerant leak sensor 85 to the information processing device 100. The operating information providing unit 44 determines the operating status of the indoor unit 50 and the refrigerant leak sensor 85 based on the operating status information of the indoor unit 50 transmitted from the indoor unit 50 and the output information of the leak detection signal Lk_ON of the refrigerant leak sensor 85. Recognize the detection status of refrigerant leaks by

The indoor unit 50 includes the above-described indoor unit control unit 52 and an indoor unit communication circuit 51. The indoor unit communication circuit 51 communicates with the outdoor unit 20 via the communication line 12. The indoor unit control unit 52 includes an indoor unit processor 60, an indoor unit memory 65, and the like, and the indoor unit memory 65 stores an indoor unit program 66 for controlling the indoor unit 50. The indoor unit processor 60 reads and executes the indoor unit program 66, so that the indoor unit communication control section 61 controls communication between the indoor unit communication circuit 51 and the outdoor unit 20.

The indoor unit communication control unit 61 receives the above-mentioned operating status information of the indoor unit 50, specification information of the refrigerant leak sensor 85, output information of the sensor error signal SEr of the refrigerant leak sensor 85, leakage detection signal Lk_ON of the refrigerant leak sensor 85, etc. , is transmitted to the outdoor unit 20.

[4. Configuration of information processing device]
The configuration of the information processing device 100 will be described with reference to FIG. 4. The information processing device 100 is a computer system including an information processing device communication circuit 101, an information processing device processor 110, an information processing device memory 120, and the like.

The information processing device communication circuit 101 communicates with the air conditioner 10 and the terminal device 200 used by the administrator P of the air conditioner 10 via the communication network 300. Note that the information processing device communication circuit 101 may be configured to directly communicate with the air conditioner 10 and the terminal device 200 without going through the communication network 300. Alternatively, the terminal device 200 may be included in the information processing device 100.

The information processing device memory 120 records an information processing device program 121 for controlling the information processing device 100, a sensor information DB 122 in which information regarding the refrigerant leak sensor 85 is recorded, and information regarding the operating status of the air conditioner 10. A driving status DB 123 is stored. The information processing device processor 110 reads and executes the information processing device program 121, thereby functioning as the information processing device communication control section 111, self-diagnosis function information acquisition section 112, sensor information notification section 113, and use environment information notification section 114. Function.

The information processing device communication control unit 111 controls communication between the air conditioner 10 and the terminal device 200 via the communication network 300 by the information processing device communication circuit 101. The self-diagnosis function information acquisition unit 112 receives and acquires the self-diagnosis function information transmitted from the air conditioner 10 by the information processing device communication control unit 111. The sensor information notification unit 113 recognizes whether the refrigerant leak sensor 85 has a self-diagnosis function based on the self-diagnosis function information. The sensor information reporting unit 113 then distinguishes between cases where the refrigerant leak sensor 85 has a self-diagnosis function and cases where the refrigerant leak sensor 85 does not have a self-diagnosis function, as will be described in detail later. Information regarding the inspection of the refrigerant leak sensor 85 is transmitted to the terminal device 200.

The usage environment information notification unit 114 receives and acquires the driving status information transmitted from the air conditioner 10, and records the driving status information in the driving status DB 123. The usage environment information reporting unit 114 recognizes the usage environment of the air conditioner 10 based on the driving status information. The operating environment of the air conditioner 10 includes the operating time of the indoor unit 50, the temperature and humidity of the room in which the indoor unit 50 is installed, and the like. The usage environment information notification unit 114 transmits usage environment information indicating the usage environment of the air conditioner 10 to the terminal device 200.

The terminal device 200 displays the information regarding the inspection of the refrigerant leak sensor 85 and the usage environment information of the air conditioner 10 transmitted from the air conditioner 10 on the display unit of the terminal device 200 . The administrator P of the air conditioner 10 checks this information displayed on the display section of the terminal device 200 and inspects the refrigerant leak sensor 85.

[5. Refrigerant leak sensor inspection support processing]
The support process for checking the refrigerant leak sensor 85 executed by the configuration of the information processing apparatus 100 shown in FIG. 4 will be described according to the flowcharts shown in FIGS. 5 and 6. 5, when the air conditioner 10 is installed and the air conditioner 10 starts to be used, when the refrigerant leak sensor 85 is replaced due to repair or inspection of the air conditioner 10, The process according to the flowchart shown in FIG. 6 is executed.

In the process according to the flowcharts of FIGS. 5 and 6, in the management method of the present disclosure, the information processing device determines whether or not the refrigerant leak sensor is equipped with a self-diagnosis function based on the self-diagnosis function information, and When the leakage sensor is equipped with a self-diagnosis function, the refrigerant leak sensor receives self-diagnosis result information indicating the diagnosis result from the refrigeration cycle equipment and notifies the self-diagnosis result information, and the refrigerant leakage sensor has the self-diagnosis function. If the refrigerant leakage sensor is not provided, this corresponds to the step of notifying the inspection timing of the refrigerant leakage sensor.

In step S1 of FIG. 5, the self-diagnosis function information acquisition unit 112 transmits a command requesting the air conditioner 10 to transmit the self-diagnosis function information. In subsequent step S2, when the self-diagnosis function information acquisition unit 112 receives the self-diagnosis function information transmitted from the air conditioner 10, the process proceeds to step S3.

In step S3, the sensor information notification unit 113 recognizes whether or not the refrigerant leak sensor 85 is equipped with a self-diagnosis function based on the self-diagnosis function information. In subsequent step S4, when the refrigerant leak sensor 85 is equipped with a self-diagnosis function, the sensor information notification unit 113 advances the process to step S5, and when the refrigerant leak sensor 85 is not equipped with a self-diagnosis function, the process proceeds to step S5, and when the refrigerant leak sensor 85 is not equipped with a self-diagnosis function, the process proceeds to step S5. The process advances to step S10.

Steps S5 and S6 are processes when the refrigerant leak sensor 85 is equipped with a self-diagnosis function. In step S5, when the sensor information notification unit 113 receives the self-diagnosis result information of the refrigerant leak sensor 85 from the air conditioner 10, the process proceeds to step S6. In the next step S6, the sensor information notification unit 113 transmits the self-diagnosis result information of the refrigerant leak sensor 85 to the terminal device 200 used by the administrator P. The self-diagnosis result information indicates that the refrigerant leak sensor 85 is malfunctioning (sensor error signal SEr is output) or that the refrigerant leak sensor 85 is operating normally (sensor error signal SEr is output). (not shown).

The terminal device 200 displays the content of the self-diagnosis result information transmitted from the information processing device 100 on the display unit of the terminal device 200. When the display section of the terminal device 200 displays a scene indicating that the refrigerant leak sensor 85 is malfunctioning, the administrator P goes to the building etc. where the air conditioner 10 is installed and Performs maintenance such as inspection, repair, and replacement of the refrigerant leak sensor 85.

Steps S10 to S13 in FIG. 6 are processes corresponding to the case where the refrigerant leak sensor 85 is not equipped with a self-diagnosis function. In step S10, the sensor information notification unit 113 sets the next inspection timing for the refrigerant leak sensor 85. The next inspection time for the refrigerant leak sensor 85 is set, for example, when one year has passed since the inspection was completed.

In subsequent step S11, the sensor information notification unit 113 advances the process to step S12 when the inspection time of the refrigerant sensor approaches (for example, two weeks before the inspection time). In step S12, the sensor information notification unit 113 transmits inspection timing information that informs the terminal device 200 used by the administrator P of the air conditioner 10 of the inspection timing of the refrigerant leak sensor 85.

When the terminal device 200 receives the inspection timing information from the information processing device 100, the terminal device 200 displays a notification screen indicating the inspection timing of the refrigerant leak sensor 85 on the display unit of the terminal device 200, and informs the administrator P. Urges inspection of the refrigerant leak sensor 85. When the administrator P completes the inspection of the refrigerant leak sensor 85, the administrator P operates the terminal device 200 to transmit inspection completion information indicating that the inspection of the refrigerant leak sensor 85 is completed to the information processing device 100.

In the next step S13, when the sensor information notification unit 113 receives the inspection completion information of the refrigerant leak sensor 85 from the terminal device 200, it advances the process to step S10, and thereby the next inspection of the refrigerant leak sensor 85 is performed. The time is set.

[6. Air conditioner information provision processing]
According to the flowchart shown in FIG. 7, information provision processing for the information processing apparatus 100 executed by the configuration of the air conditioner 10 shown in FIG. 3 will be described. The air conditioner 10 repeatedly executes the process according to the flowchart shown in FIG.

In step S50 of FIG. 7, when the self-diagnosis function information providing unit 42 receives a command requesting transmission of self-diagnosis function information from the information processing apparatus 100, the process proceeds to step S51, and from the information processing apparatus 100, If a command requesting transmission of self-diagnosis function information is not received, the process advances to step S60. In step S51, the self-diagnosis function information providing unit 42 transmits self-diagnosis function information indicating whether the refrigerant leak sensor 85 is equipped with a self-diagnosis function to the information processing device 100.

In step S51, the self-diagnosis function information providing unit 42 transmits the self-diagnosis function information to the information processing device 100. This corresponds to a step of transmitting self-diagnosis function information indicating whether or not a self-diagnosis function for diagnosing is provided to the information processing device.

In step S60, the self-diagnosis result information providing unit 43 determines whether or not it is time to transmit the self-diagnosis result information. The timing for transmitting the self-diagnosis result information is a predetermined operation confirmation of the refrigerant leak sensor 85 when the refrigerant leak sensor 85 outputs a sensor error signal SEr indicating that the refrigerant leak sensor 85 is malfunctioning. When a certain point is reached, etc.

Then, the self-diagnosis result information providing unit 43 advances the process to step S61 when the timing to transmit the self-diagnosis result information has come, and advances the process to step S70 when the timing to transmit the self-diagnosis result information has not come. In step S61, the self-diagnosis result information providing unit 43 provides a self-diagnosis result indicating the determination result of whether or not the refrigerant leak sensor 85 is malfunctioning (whether or not the sensor error signal SEr is output) by the self-diagnosis function of the refrigerant leak sensor 85. The information is transmitted to the information processing device 100. In the information processing device 100 that has received the self-diagnosis result information, the self-diagnosis result information is recorded in the sensor information DB 122.

In step S70, the driving information providing unit 44 checks whether the leakage detection signal Lk_ON from the refrigerant leakage sensor 85 is input. Then, the driving information providing unit 44 advances the process to step S71 when the leak detection signal Lk_ON is input, and advances the process to step S80 when the leak detection signal Lk_ON is not input. In step S71, the operation information providing unit 44 transmits refrigerant leak detection information indicating that refrigerant leak has been detected to the information processing device 100.

In the information processing device 100 that has received the refrigerant leak detection information, the refrigerant leak detection information is recorded in the sensor information DB 122. The information processing device 100 transmits refrigerant leak occurrence information that reports a refrigerant leak to the terminal device 200, and the terminal device 200 that has received the refrigerant leak occurrence information displays a notification screen that prompts a response to the refrigerant leak on the terminal device. 200 display section. This supports the administrator P to promptly respond to refrigerant leakage.

In step S80, the driving information providing unit 44 determines whether it is time to transmit the driving status information of the air conditioner 10. The transmission timing of the driving status information is set, for example, to a predetermined time, the time when the air conditioner 10 finishes operating, or the like. Then, the driving information providing unit 44 advances the process to step S81 when it is the timing to transmit the driving status information, and advances the process to step S50 when the timing to transmit the driving status information has not arrived.

In step S<b>81 , the driving information providing unit 44 transmits the driving status information of the air conditioner 10 to the information processing device 100 . In the information processing device 100 that has received the driving status information, the driving status information of the air conditioner 10 is recorded in the driving status DB 123.

[7. Effects, etc.]
As described above, in the present embodiment, the management system 1 includes the air conditioner 10 and the information processing device 100, and determines whether the refrigerant leak sensor 85 provided in the indoor unit 50 has a self-diagnosis function. Self-diagnosis function information indicating this is transmitted from the air conditioner 10 to the information processing device 100. The information processing device 100 determines whether or not the refrigerant leak sensor 85 is equipped with a self-diagnosis function based on the self-diagnosis function information, and when the refrigerant leak sensor 85 is equipped with a self-diagnosis function, Self-diagnosis result information indicating the diagnosis result by the diagnostic function is received from the air conditioner 10 and the self-diagnosis result information is sent to the terminal device 200 to notify the administrator P, and the refrigerant leak sensor 85 has the self-diagnosis function. If the refrigerant leakage sensor is not equipped, the administrator P is notified by transmitting information indicating the inspection timing of the refrigerant leakage sensor to the terminal device 200.
In this way, by separately managing the refrigerant leak sensor 85 depending on whether the refrigerant leak sensor 85 has a self-diagnosis function or not, the refrigerant leak sensor having a self-diagnosis function can be inspected. In addition, it is possible to encourage the regular inspection of refrigerant leak sensors that do not have a self-diagnosis function, and to support the appropriate use of refrigerant leak sensors.

(Other embodiments)
As mentioned above, the above embodiment has been described as an example of the technology disclosed in this application. However, the technology in the present disclosure is not limited to this, and can also be applied to embodiments in which changes, replacements, additions, omissions, etc. are made. Therefore, other embodiments will be illustrated below.

In the embodiment described above, when the information processing device 100 recognizes malfunction of the refrigerant leak sensor 85 from the self-diagnosis result information sent from the air conditioner 10, the operating status information is sent from the air conditioner 10. Information indicating the cause of the malfunction of the refrigerant leak sensor 85 estimated from the above may be transmitted from the information processing device 100 to the terminal device 200, and the cause may be displayed on the display unit of the terminal device 200. The following factors are assumed to be the cause of malfunction of the refrigerant leak sensor 85, for example.
First factor: The temperature of the room in which the indoor unit 50 is installed, which is detected by the temperature sensor 83, is below a predetermined temperature. → Condensation has adhered to the refrigerant leak sensor 85.
Second factor: The humidity of the room in which the indoor unit 50 is installed, as detected by the humidity sensor 84, is higher than a predetermined humidity → dew condensation has adhered to the refrigerant leakage sensor 85.
Third factor: the indoor unit 50 has not been operated for a predetermined period of time or more → dust has adhered to the refrigerant leakage sensor 85.
Fourth factor: the cumulative operating time of the indoor unit 50 is longer than a predetermined period → dust is attached to the refrigerant leakage sensor 85.
The administrator P can take an appropriate response to the malfunction of the refrigerant leak sensor 85 by confirming the factors presumed to be the cause of the malfunction of the refrigerant leak sensor 85.

In the above embodiment, history information of diagnosis results based on self-diagnosis result information transmitted from the air conditioner 10 is transmitted from the information processing device 100 to the terminal device 200, and displayed on the display section of the terminal device 200. History information may also be displayed. The history information includes the number and frequency of malfunctions of the refrigerant leak sensor 85 diagnosed due to disturbances such as dew condensation and dust accumulation in the past. By checking the history information, the administrator P can grasp whether the environment in which the indoor unit 50 is used is such that the refrigerant leak sensor 85 is easily affected by external disturbances.

In the above embodiment, the information processing device 100 manages the inspection status of the refrigerant leak sensor 85, which does not have a self-diagnosis function, and the period during which the refrigerant leak sensor 85 is not inspected is equal to or longer than the first predetermined period. If the refrigerant leak sensor 85 has not been inspected for a long time, first inspection timing information is sent to the terminal device 200 to notify that the refrigerant leak sensor 85 has not been inspected for a long time, and the first inspection timing information is displayed on the display section of the terminal device 200. A notification screen prompting inspection of the refrigerant leak sensor 85 may be displayed. Thereby, it is possible to suppress omission of inspection of the refrigerant leak sensor 85 which does not have a self-diagnosis function.

In the above embodiment, the information processing device 100 manages the inspection status of the refrigerant leak sensor 85 having a self-diagnosis function, and the period during which the refrigerant leak sensor 85 is not inspected is equal to or longer than the second predetermined period. If the refrigerant leak sensor 85 has not been inspected for a long time, second inspection timing information is sent to the terminal device 200 to notify that the refrigerant leak sensor 85 has not been inspected for a long time, and is displayed on the display section of the terminal device 200. , a notification screen urging inspection of the refrigerant leak sensor 85 may be displayed. Regarding the refrigerant leak sensor 85, which has a self-diagnosis function, it may be possible to operate the refrigerant leak sensor 85 without requiring periodic inspection, but by prompting an inspection when it has not been inspected for a long time, the refrigerant leak detection by the refrigerant leak sensor 85 can be improved. Reliability can be increased.

In the embodiment described above, based on the operating status information of the air conditioner 10 transmitted from the air conditioner 10, the information processing device 100 is used in an environment where the indoor unit 50 is likely to malfunction due to disturbance in the refrigerant leak sensor. When it is determined that the indoor unit 50 is being used in the above environment, usage environment information indicating that the indoor unit 50 is being used in the above environment is sent to the terminal device 200. Then, a notification screen indicating that the indoor unit 50 is being used in the above environment may be displayed on the display unit of the terminal device 200. Thereby, the administrator P can be urged to also inspect the refrigerant leak sensor 85 when, for example, performing a periodic inspection of the indoor unit 50. The determination that the indoor unit 50 is being used in the above environment can be made, for example, in the same manner as the first to fourth factors described above.

In the embodiment described above, the self-diagnosis result of the refrigerant leak sensor 85 based on the self-diagnosis result information transmitted from the air conditioner 10 and the detection of the presence or absence of refrigerant leak by the refrigerant leak sensor 85 transmitted from the air conditioner 10 Leakage detection performance information indicating the results may be recorded in the sensor information DB 122 and stored for a third predetermined period. When the air conditioner 10 is operating normally, the leakage detection performance information indicates that the self-diagnosis function of the refrigerant leakage sensor 85 is functioning normally and no refrigerant leakage is detected. If the leakage detection record information is not saved until the third predetermined period has elapsed (for example, if the leakage detection record information is discarded due to an abnormality in the information processing apparatus 100), the information processing apparatus 100 stores the leakage detection record information in the terminal device 200. , information notifying that the leakage detection record information has disappeared is transmitted to the terminal device 200, and a notification screen indicating the disappearance of the leakage detection record information is displayed on the display unit of the terminal device 200.

The controller configuring the management system according to the present disclosure may be any controller as long as it can control the operation of the management system according to the present disclosure. When expressing the subject matter of the invention, a controller, a control means, a control unit, or words similar to these may be used in addition to the controller to control the operation of the management system of the present disclosure. The controller can be implemented in various ways. For example, a processor may be used as the controller. If a processor is used as a controller, various processes can be executed by having the processor read a program from a storage medium storing the program and executing the program by the processor. Therefore, since the processing content can be changed by changing the program stored in the storage medium, the degree of freedom in changing the control content can be increased. Examples of the processor include a CPU (Central Processing Unit) and an MPU (Micro-Processing Unit). Examples of storage media include hard disks, flash memories, and optical disks. Further, wired logic whose program cannot be rewritten may be used as the controller. Using wired logic as a controller is effective in improving processing speed. Examples of wired logic include ASIC (Application Specific Integrated Circuit). Further, the controller may be realized by combining a processor and wired logic. If a controller is realized by combining a processor and wired logic, it is possible to increase the degree of freedom in software design and improve processing speed. Further, the controller and a circuit having a function different from the controller may be configured with one semiconductor element. Examples of circuits having other functions include an A/D/D/A conversion circuit. Further, the controller may be composed of one semiconductor element or may be composed of a plurality of semiconductor elements. When configured with a plurality of semiconductor elements, each control described in the claims may be realized with different semiconductor elements. Furthermore, the controller may be configured to include a semiconductor element and passive components such as a resistor or a capacitor.

The communicator included in the management system of the present disclosure may be any communicator as long as it enables communication between the management system of the present disclosure and external devices, and communication between components of the management system. In expressing the subject matter of the invention, in addition to the communicator, communication means or communication units or It may be written as a transmitting/receiving means, a transmitting/receiving unit, or words similar to these. The communicator can be implemented in various ways. Examples of the communicator include a wireless connection with an external device via a base station or the like, or a direct wireless connection with an external device. Wireless connections with external devices via base stations etc. include, for example, IEEE802.11 compatible wireless LAN that wirelessly communicates with WiFi (registered trademark) routers, 3rd generation mobile communication systems (commonly known as 3G), and 4th generation mobile communication systems. Examples include mobile communication systems (commonly known as 4G), WiMax (registered trademark) compatible with IEEE 802.16, and LPWA (Low Power Wide Area). By using a communicator that directly wirelessly connects the device of the present disclosure and an external device, it is effective to improve the security of communication, and even in places where there is no relay device such as a WiFi (registered trademark) router, the communicator can The disclosed device can communicate with external devices. Examples of the communicator that directly wirelessly connects the device of the present disclosure and an external device include communication using Bluetooth (registered trademark), communication using NFC (Near Field Communication) via a loop antenna, or infrared communication. be.

Note that the above-described embodiments are for illustrating the technology of the present disclosure, and therefore various changes, substitutions, additions, omissions, etc. can be made within the scope of the claims or equivalents thereof.

The present disclosure is applicable to applications that support maintenance of an infrared refrigerant leak sensor provided in a refrigeration cycle device.

1 Management system 10 Air conditioner (refrigeration cycle device)
11 Refrigerant piping 12 Communication line 13 First on-off valve 14 Liquid side piping 15 Second on-off valve 16 Gas side piping 20 Outdoor unit 21 Outdoor unit communication circuit 22 Outdoor unit control unit 30 Refrigeration cycle 31 Compressor 32 Gas-liquid separator 33 Oil Separator 34 Four-way valve 35 Outdoor blower fan 36 Outdoor heat exchanger 37 Outdoor expansion valve 40 Outdoor unit processor 41 Outdoor unit communication control section 42 Self-diagnosis function information provision section 43 Self-diagnosis result information provision section 44 Operation information provision section 45 Outdoor unit memory 46 Outdoor unit program 50 Indoor unit 51 Indoor unit communication circuit 52 Indoor unit control unit 60 Indoor unit processor 61 Indoor unit communication control section 65 Outdoor unit memory 66 Indoor unit program 80 Indoor ventilation fan 81 Indoor heat exchanger 82 Indoor expansion valve 83 Temperature Sensor 84 Humidity sensor 85 Refrigerant leak sensor 100 Information processing device 101 Information processing device communication circuit 110 Information processing device processor 111 Information processing device communication control section 112 Self-diagnosis function information acquisition section 113 Sensor information notification section 114 Usage environment information notification section 120 Information Processing device memory 121 Information processing device program 122 Sensor information DB
123 Driving status DB
200 Terminal device 300 Communication network P Air conditioner administrator

Claims (11)

A management system comprising: a refrigeration cycle device equipped with an infrared refrigerant leak sensor for detecting refrigerant leakage; and an information processing device, the management system communicating between the refrigeration cycle device and the information processing device. hand,
The refrigeration cycle device transmits self-diagnosis function information indicating whether the refrigerant leak sensor is equipped with a self-diagnosis function for diagnosing the operating status of the refrigerant leak sensor to the information processing device,
The information processing device determines whether or not the refrigerant leak sensor is equipped with the self-diagnosis function based on the self-diagnosis function information, and when the refrigerant leak sensor is equipped with the self-diagnosis function. receives self-diagnosis result information indicating a diagnosis result by the self-diagnosis function from the refrigeration cycle device and notifies the self-diagnosis result information, and when the refrigerant leak sensor is not equipped with the self-diagnosis function, A management system that notifies the inspection timing of the refrigerant leak sensor. The refrigeration cycle device transmits operating status information indicating the operating status of the refrigeration cycle device to the information processing device,
When malfunction of the refrigerant leak sensor is recognized from the self-diagnosis result information, the information processing device notifies the cause of the malfunction of the refrigerant leak sensor estimated from the driving status information. Management system according to item 1. The management system according to claim 1 or 2, wherein the information processing device notifies history information of diagnosis results based on the past self-diagnosis result information received from the refrigeration cycle device. The information processing device may detect the refrigerant leak sensor when the refrigerant leak sensor is not equipped with the self-diagnosis function and the period during which the refrigerant leak sensor is not inspected is equal to or longer than a first predetermined period. The management system according to claim 1 or claim 2, wherein the management system notifies the first inspection timing information to prompt inspection of. The information processing device is configured such that the refrigerant leak sensor is equipped with the self-diagnosis function, and when the period during which the refrigerant leak sensor is not inspected is equal to or longer than a second predetermined period, the refrigerant leak sensor is inspected. The management system according to claim 1 or claim 2, wherein the management system notifies the second inspection timing information to prompt the inspection of. The refrigeration cycle device transmits operating status information indicating the operating status of the refrigeration cycle device to the information processing device,
The information processing device determines whether the refrigeration cycle device is used in an environment where the refrigerant leakage sensor is likely to malfunction due to disturbance, based on the operating status information, and determines whether the refrigeration cycle device The management system according to claim 1, wherein when it is determined that the refrigeration cycle device is being used in the environment, usage environment information indicating that the refrigeration cycle device is being used in the environment is notified. The information processing device transmits leakage detection performance information indicating a diagnosis result of the refrigerant leakage sensor based on the self-diagnosis result information and a detection result of the presence or absence of refrigerant leakage by the refrigerant leakage sensor transmitted from the refrigeration cycle device. The management system according to claim 1 or claim 2, wherein the management system stores the information for a third predetermined period. A management system that includes a refrigeration cycle device equipped with an infrared refrigerant leak sensor that detects refrigerant leakage and an information processing device, and communicates between the refrigeration cycle device and the information processing device, A management method carried out,
a step in which the refrigeration cycle device transmits, to the information processing device, self-diagnosis function information indicating whether the refrigerant leak sensor is equipped with a self-diagnosis function for diagnosing the operating status of the refrigerant leak sensor;
When the information processing device determines whether the refrigerant leak sensor is equipped with the self-diagnosis function based on the self-diagnosis function information, and the refrigerant leak sensor is equipped with the self-diagnosis function. receives self-diagnosis result information indicating a diagnosis result by the self-diagnosis function from the refrigeration cycle device and notifies the self-diagnosis result information, and when the refrigerant leak sensor is not equipped with the self-diagnosis function, a step of notifying the inspection timing of the refrigerant leak sensor;
Management methods including. a communication control unit that communicates with a refrigeration cycle device equipped with an infrared refrigerant leak sensor that detects refrigerant leak;
The communication control unit receives self-diagnosis function information transmitted from the refrigeration cycle device and indicates whether the refrigerant leak sensor is equipped with a self-diagnosis function for diagnosing the operating status of the refrigerant leak sensor. a self-diagnosis function information acquisition unit to acquire;
Based on the self-diagnosis function information, it is determined whether or not the refrigerant leak sensor is equipped with the self-diagnosis function, and when the refrigerant leak sensor is equipped with the self-diagnosis function, the self-diagnosis function is The communication control unit receives self-diagnosis result information indicating a diagnosis result from the refrigeration cycle device and notifies the self-diagnosis result information, and when the refrigerant leak sensor is not equipped with the self-diagnosis function, a sensor information notification unit that notifies the inspection timing of the refrigerant leak sensor;
An information processing device comprising: computer,
a communication control unit that communicates with a refrigeration cycle device equipped with an infrared refrigerant leak sensor that detects refrigerant leak;
The communication control unit receives self-diagnosis function information transmitted from the refrigeration cycle device and indicates whether the refrigerant leak sensor is equipped with a self-diagnosis function for diagnosing the operating status of the refrigerant leak sensor. a self-diagnosis function information acquisition unit to acquire;
Based on the self-diagnosis function information, it is determined whether or not the refrigerant leak sensor is equipped with the self-diagnosis function, and when the refrigerant leak sensor is equipped with the self-diagnosis function, the self-diagnosis function is The communication control unit receives self-diagnosis result information indicating a diagnosis result from the refrigeration cycle device and notifies the self-diagnosis result information, and when the refrigerant leak sensor is not equipped with the self-diagnosis function, a sensor information notification unit that notifies the inspection timing of the refrigerant leak sensor;
A program that makes it work. A refrigeration cycle in which refrigerant circulates,
an infrared refrigerant leak sensor that detects leakage of the refrigerant;
a communication control unit that communicates with an external device;
Providing self-diagnosis function information in which the communication control unit transmits self-diagnosis function information indicating whether or not the refrigerant leak sensor is equipped with a self-diagnosis function for diagnosing the operating status of the refrigerant leak sensor to the external device. Department and
A refrigeration cycle device comprising:

Images