JP6945326B2 - Air conditioner, air conditioning system and communication quality measurement method - Google Patents

Description

The present invention relates to a technique for measuring the communication quality of an air conditioning system.

For example, a technique has been proposed for the purpose of making it easier to detect the presence or absence of a transmission abnormality when a new air conditioning system in which a plurality of air conditioners are connected is constructed (for example, Patent Document 1).

Patent Document 1 describes information on indoor air-conditioning capacity in an air-conditioning system configured such that the ratio of the total indoor air-conditioning capacity of a plurality of indoor units to the total outdoor air-conditioning capacity of a plurality of outdoor units has a predetermined relationship. It is disclosed that information on the outdoor air-conditioning capacity is acquired, and the presence or absence of a transmission abnormality is determined by comparing the total indoor air-conditioning capacity calculated based on the acquired information with the total outdoor air-conditioning capacity. ..

Japanese Unexamined Patent Publication No. 2012-127552

However, in the above-mentioned disclosure technique of Patent Document 1, although the occurrence of a transmission abnormality (that is, a communication abnormality) can be detected, the communication quality including a state in which the communication is not good, that is, a state in which a communication abnormality is expected in the future is included. Communication quality cannot be detected.

The present invention has been made to solve the above problems, and an object of the present invention is to provide an air conditioner or the like capable of easily and appropriately measuring communication quality in an air conditioning system in which a plurality of air conditioners are connected. And.

In order to achieve the above object, the air conditioner according to the present invention is
Command receiving means for receiving control commands from other air conditioners,
Waveform feature detection means that detects the waveform feature of the communication signal in the received control command and stores the waveform feature data in which the detected waveform feature is associated with the identification information of the other air conditioner in a data table. When,
A waveform feature transmission means for transmitting waveform feature data stored in the data table to a centralized monitoring device at a predetermined timing, and a waveform feature transmission means.
Waveform feature receiving means for receiving waveform feature data from other air conditioners, and
A relay destination search means for searching for another air conditioner capable of directly communicating with the centralized monitoring device is provided.
The waveform feature amount transmitting means is
When it is not possible to directly communicate with the centralized monitoring device, the waveform feature data stored in the data table is transmitted to another air conditioner searched by the relay destination search means.
When the waveform feature data from another air conditioner is received by the waveform feature receiving means, the waveform feature data is transferred to the centralized monitoring device.
If there is no other air conditioner that cannot directly communicate with the centralized monitoring device and can directly communicate with the centralized monitoring device, error notification is performed by at least one of light emission, sound output, and message display. To do .

According to the present invention, the waveform feature amount of the communication signal in the control command received from another air conditioner is detected, and the waveform feature amount data in which the detected waveform feature amount is associated with the identification information of the other air conditioner is generated. Send to the centralized monitoring device. Therefore, it is possible to easily and appropriately measure the communication quality in the air conditioning system.

The figure which shows the whole structure of the air-conditioning system which concerns on embodiment of this invention. Block diagram showing the configuration of the air conditioner according to this embodiment The figure for demonstrating the secondary storage device provided in the air conditioner of this embodiment. A block diagram showing a functional configuration of a control unit included in the air conditioner of the present embodiment. The figure which shows the waveform example of the control command in this embodiment The figure for demonstrating the case where the pulse width is detected as the waveform feature amount in this embodiment. A flowchart showing a procedure of communication quality measurement processing executed by the air conditioner of the present embodiment. Block diagram showing the configuration of the centralized monitoring device according to this embodiment The figure which shows the display example (the 1) of the diagnosis result of communication quality in this embodiment. The figure which shows the display example (the 2) of the diagnosis result of communication quality in this embodiment.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

FIG. 1 is a diagram showing a configuration of an air conditioning system 1 according to an embodiment of the present invention. The air conditioning system 1 is, for example, a system that enables centralized management of air conditioning in a building such as an office building. As shown in FIG. 1, the air conditioning system 1 includes a centralized monitoring device 2 and a plurality of air conditioners 3.

The centralized monitoring device 2 and each of the plurality of air conditioners 3 are connected so as to be able to communicate with each other via the communication line 4.

Each of the plurality of air conditioners 3 is an outdoor unit, an indoor unit, or a remote controller, and as shown in FIG. 2, the communication interface 30, the main unit 31, the secondary storage device 32, and the waveform acquisition unit 33 are used. And a control unit 34.

The communication interface 30 includes an interface for communicating with the centralized monitoring device 2 and another air conditioner 3 via the communication line 4. The main unit 31 is a component for realizing the original function of the air conditioner 3. When the air conditioner 3 is an outdoor unit, the main unit 31 includes a compressor, a condenser, an expansion valve, an evaporator and the like. When the air conditioner 3 is an indoor unit, the main unit 31 includes a fan, a heat exchanger, a temperature sensor, and the like. When the air conditioner 3 is a remote controller, the main unit 31 includes a user interface device, more specifically, an input device such as a push button, a touch panel, and a touch pad, and a display such as an organic EL display and a liquid crystal display. Is done.

The secondary storage device 32 is composed of, for example, a readable / writable non-volatile semiconductor memory such as an EEPROM (Electrically Erasable Programmable Read-Only Memory) and a flash memory. As shown in FIG. 3, the secondary storage device 32 stores the communication quality measurement program 320 and the waveform feature amount table 321. In addition to this, the secondary storage device 32 stores various programs related to the operation of the main unit 31 and data used when executing these programs.

The communication quality measurement program 320 is a computer program executed by the control unit 34. The communication quality measurement program 320 describes a process for measuring the quality (that is, communication quality) in communication with another air conditioner 3 and transmitting the measured communication quality to the centralized monitoring device 2.

The waveform feature amount table 321 is a data table for storing the waveform feature amount of the communication data received from the other air conditioner 3 in association with the information for identifying the other air conditioner 3.

Returning to FIG. 2, the waveform acquisition unit 33 acquires communication data related to air conditioning control, that is, waveform data of control commands, received from another air conditioner 3 via the communication interface 30. The waveform acquisition unit 33 is composed of, for example, a digital oscilloscope, and outputs the acquired waveform data to the control unit 34.

The control unit 34 includes a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), and the like (none of which are shown), and controls the air conditioner 3 in an integrated manner. Functionally, as shown in FIG. 4, the control unit 34 includes a waveform feature detection unit 340, a data notification unit 341, a relay destination search unit 342, a data transmission / reception unit 343, and an air conditioning control unit 344. Be prepared. These functional units are realized by the CPU executing the communication quality measurement program 320 stored in the secondary storage device 32.

The waveform feature amount detecting unit 340 is an example of the waveform feature amount detecting means included in the air conditioner according to the present invention. The waveform feature amount detection unit 340 detects the waveform feature amount from the waveform data acquired by the waveform acquisition unit 33. Specifically, the waveform feature amount detection unit 340 detects the maximum value of the amplitude, that is, the crest value from the above waveform data (see FIG. 5). In the air conditioning system 1, each air conditioner 3 serially communicates control commands related to air conditioning control. For example, a communication signal in which a control command is encoded is transmitted between the air conditioners 3 by a method as shown in FIGS. 5A to 5C.

The waveform feature amount may be the pulse width. When a control command is received, a normal communication interface such as the communication interface 30 detects the start of the first bit of the received signal as an edge, and determines the level of the received signal at a predetermined timing for each bit from the time of edge detection. , Bit judgment is performed. On the other hand, as shown in FIG. 6, the waveform feature amount detection unit 340 determines the level of the received signal for a predetermined number of times (for example, 8 times) that the period originally has a pulse, and pulses the rate of level detection. Calculated as width. FIG. 6 shows an example of the RZ method. FIG. 6A shows a case where the pulse width is 8/8 and is normal, and FIG. 6B shows a case where the pulse width is 4/8 and waveform rounding occurs. (C) shows a case where the pulse width is 6/8 and noise is generated.

The waveform feature amount detection unit 340 associates the waveform feature amount detected as described above with the information for identifying the air conditioner 3 of the communication partner (hereinafter, referred to as device ID (identification)). The data is stored in the waveform feature amount table 321.

The data notification unit 341 is an example of the waveform feature amount transmitting means included in the air conditioner according to the present invention. The data notification unit 341 notifies the centralized monitoring device 2 of the communication quality between the own unit (the air conditioner 3) and the other air conditioner 3 at a predetermined timing. Specifically, the data notification unit 341 generates communication quality data for notifying the centralized monitoring device 2 of the detected waveform feature amount at regular intervals (for example, at regular time intervals or at predetermined time intervals). , Instruct the data transmission / reception unit 343 to transmit. The communication quality data includes a destination ID, information indicating that the communication quality is notified, and waveform feature data stored in the waveform feature table 321. The data notification unit 341 determines whether or not it can directly communicate with the centralized monitoring device 2, and if it can communicate directly, sets the device ID of the centralized monitoring device 2 as the destination ID.

On the other hand, when direct communication with the centralized monitoring device 2 is not possible due to a wiring error or the like, the data notification unit 341 instructs the relay destination search unit 342 to search for the air conditioner 3 which is the relay destination of the communication quality data. Whether or not direct communication is possible is determined by, for example, whether or not a reception response is returned from the centralized monitoring device 2 within a certain period of time when the communication quality data is first transmitted to the centralized monitoring device 2. Alternatively, each air conditioner 3 periodically checks the communication with the centralized monitoring device 2, and the data notification unit 341 can directly communicate with the centralized monitoring device 2 based on the latest communication check result. May be determined.

The relay destination search unit 342 is an example of the relay destination search means included in the air conditioner according to the present invention. The relay destination search unit 342 searches for another air conditioner 3 capable of communicating with its own unit and capable of directly communicating with the centralized monitoring device 2. For example, the relay destination search unit 342 sequentially inquires one or a plurality of other air conditioners 3 with which the own unit can communicate whether or not it is possible to directly communicate with the centralized monitoring device 2. Then, when a response indicating that direct communication is possible is returned in response to the inquiry, the relay destination search unit 342 notifies the device ID of the other air conditioner 3 of the response source as the search result of the relay destination. Respond to unit 341.

When another air conditioner 3 capable of directly communicating with the centralized monitoring device 2 cannot be searched, the relay destination search unit 342 responds to the data notification unit 341 that the corresponding air conditioner 3 does not exist.

When the device ID is returned from the relay destination search unit 342, the data notification unit 341 sets the device ID as the transmission destination ID in the communication quality data and instructs the data transmission / reception unit 343 to transmit. On the other hand, when there is a response from the relay destination search unit 342 that the corresponding air conditioner 3 does not exist, the data notification unit 341 causes the LED included in the air conditioner 3 to emit light in a predetermined manner, or causes the air conditioner 3 to emit light. It provides error notification such as outputting an electronic sound from the speaker provided in the air conditioner. At that time, when the air conditioner 3 is a remote controller, a message indicating that an error has occurred may be displayed on the display.

Further, when the data notification unit 341 receives the communication quality data from the other air conditioner 3 by the data transmission / reception unit 343, the data notification unit 341 transfers the communication quality data to the centralized monitoring device 2. Specifically, the data notification unit 341 updates the transmission destination ID of the communication quality data to the device ID of the centralized monitoring device 2, and instructs the data transmission / reception unit 343 to transmit the data.

Further, when the data notification unit 341 receives the above inquiry (hereinafter referred to as inquiry data) from another air conditioner 3 by the data transmission / reception unit 343, can the own unit directly communicate with the centralized monitoring device 2? A response indicating whether or not to use is transmitted to the inquiring air conditioner 3 via the data transmission / reception unit 343.

The data transmission / reception unit 343 is an example of a command receiving means and a waveform feature amount receiving means included in the air conditioner according to the present invention. The data transmission / reception unit 343 receives a control command or communication quality data from another air conditioner 3 via the communication interface. The data transmission / reception unit 343 supplies the received control command to the air conditioning control unit 344. Further, as described above, the data transmission / reception unit 343 supplies the received communication quality data to the data notification unit 341.

Further, the data transmission / reception unit 343 transmits the control command generated by the air conditioning control unit 344 to another air conditioner 3 via the communication interface 30. Further, as described above, the data transmission / reception unit 343 transmits the communication quality data generated by the data notification unit 341 to the centralized monitoring device 2 or another air conditioner 3 via the communication interface 30. Further, the data transmission / reception unit 343 transmits the communication quality data whose transmission destination ID has been updated by the data notification unit 341 to the centralized monitoring device 2 via the communication interface 30.

When the air conditioning control unit 344 receives a control command from the data transmission / reception unit 343, the air conditioning control unit 344 gives an operation instruction to the main unit 31 according to the content of the control command. In addition, the data transmission / reception unit generates a control command according to an operation instruction from the main unit 31 (for example, an operation instruction according to a user's operation) and transmits the control command to another air conditioner 3 that is the target of the operation instruction. Instruct 343.

FIG. 7 is a flowchart showing a procedure of communication quality measurement processing executed by each air conditioner 3. If the data transmission / reception unit 343 has not received a control command from another air conditioner 3 via the communication interface 30 (step S101; NO), the process proceeds to step S106. On the other hand, when the data transmission / reception unit 343 receives a control command from another air conditioner 3 (step S101; YES), the waveform acquisition unit 33 acquires the waveform data of the control command (step S102). The waveform feature amount detection unit 340 detects the waveform feature amount from the acquired waveform data (step S103), and obtains the waveform feature amount data in which the detected waveform feature amount is associated with the device ID of the source air conditioner 3. It is saved in the waveform feature amount table 321 (step S104).

After step S104, the air conditioning control unit 344 instructs the main unit 31 to operate according to the control command (step S105). Then, the process returns to step S101.

When the data transmission / reception unit 343 has not received the communication quality data from the other air conditioner 3 via the communication interface 30 (step S106; NO), the process proceeds to step S108. On the other hand, when the data transmission / reception unit 343 receives the communication quality data from the other air conditioner 3 (step S106; YES), the data notification unit 341 centrally monitors the communication quality data via the data transmission / reception unit 343. (Step S107). Then, the process returns to step S101.

If the data transmission / reception unit 343 has not received inquiry data from another air conditioner 3 via the communication interface 30 (step S108; NO), the process proceeds to step S110. On the other hand, when the data transmission / reception unit 343 receives the inquiry data from the other air conditioner 3 (step S108; YES), the data notification unit 341 responds indicating whether or not the own unit can directly communicate with the centralized monitoring device 2. Is returned to the air conditioner 3 of the inquiry source (step S109). Then, the process returns to step S101.

In step S110, the data notification unit 341 determines whether or not it is the notification timing of the communication quality data. For example, the data notification unit 341 may determine that it is the notification timing of the communication quality data when a predetermined time has elapsed since the last time the communication quality data generated by the own machine was transmitted, or the current time is set. When the time reaches a predetermined time, it may be determined that it is the notification timing of the communication quality data.

If it is not the communication quality data notification timing (step S110; NO), the process returns to step S101. On the other hand, when it is the notification timing of the communication quality data (step S110; YES), the data notification unit 341 generates the communication quality data as described above, and the centralized monitoring device 2 or another via the data transmission / reception unit 343. It is transmitted to the air conditioner (step S111). Then, the process returns to step S101.

Subsequently, the centralized monitoring device 2 will be described. The centralized monitoring device 2 is installed in a place such as a management room in the building where only persons concerned can enter. As shown in FIG. 8, the centralized monitoring device 2 includes a display 20, an input device 21, a communication interface 22, a secondary storage device 23, and a control unit 24.

The display 20 is composed of, for example, a CRT display, a liquid crystal display, an organic EL display, a plasma display, or the like. The display 20 displays information on the communication quality of the air conditioning system 1 under the control of the control unit 24.

The input device 21 includes, for example, a keyboard, a mouse, a keypad, a touch pad, a touch panel, and the like. The input device 21 receives an operation by an administrator or the like, and sends a signal related to the received operation to the control unit 24. When the input device 21 is a touch panel, it is installed on the display 20.

The communication interface 22 is an interface for communicating with each of the plurality of air conditioners 3 via the communication line 4.

The secondary storage device 23 includes an EEPROM (Electrically Erasable Programmable Read-Only Memory), a readable / writable non-volatile semiconductor memory such as a flash memory, an HDD (Hard Disk Drive), or the like. The secondary storage device 23 stores the communication quality diagnosis program 230 and the collected data table 231.

The communication quality diagnosis program 230 is a computer program executed by the control unit 24. The communication quality diagnosis program 230 describes a process for diagnosing the communication quality of the air conditioning system 1. The collected data table 231 is a data table for storing the communication quality data collected from each air conditioner 3.

The control unit 24 includes a CPU, a ROM, a RAM, and the like (none of which are shown), and controls the centralized monitoring device 2 in an integrated manner. The control unit 24 functionally includes a communication quality data collection unit 240, a communication quality diagnosis unit 241 and a diagnosis result output unit 242. These functional units are realized by the CPU executing the communication quality diagnosis program 230 stored in the secondary storage device 23.

The communication quality data collection unit 240 receives the communication quality data sent from each air conditioner 3 as described above, and stores the communication quality data in the collection data table 231.

The communication quality diagnosis unit 241 is an example of the communication quality diagnosis means included in the centralized monitoring device according to the present invention. The communication quality diagnosis unit 241 diagnoses the communication quality in the air conditioning system 1 based on the communication quality data from each air conditioner 3 stored in the collected data table 231. Specifically, the communication quality diagnosis unit 241 sequentially picks up the waveform feature amount from each of the one or a plurality of waveform feature amount data included in the communication quality data from each air conditioner 3, and compares it with a predetermined threshold value. For example, when the waveform feature amount is a crest value, the threshold value indicates a lower limit of the crest value considered to have good communication quality. The lower limit of the peak value is an arbitrary design item. When the picked up peak value is smaller than the threshold value, the communication quality diagnosis unit 241 determines that the communication quality between the air conditioners 3 (that is, the pair of the air conditioners 3) is not good.

Alternatively, when the waveform feature amount is a pulse width, the threshold value indicates a lower limit of the pulse width (that is, the rate of level detection) considered to have good communication quality. The lower limit of the pulse width is an arbitrary design matter. When the picked-up pulse width is smaller than the threshold value, the communication quality diagnosis unit 241 determines that the communication quality between the air conditioners 3 (that is, the pair of the air conditioners 3) is not good.

Further, when there are a plurality of pairs of air conditioners 3 that are judged to have poor communication quality and there are overlapping air conditioners 3 in different pairs, the communication quality diagnosis unit 241 determines that the air conditioner 3 has poor communication quality. Identify as.

The diagnosis result output unit 242 is an example of the diagnosis result output means included in the centralized monitoring device according to the present invention. The diagnosis result output unit 242 outputs the diagnosis result of the communication quality diagnosis unit 241 to the display 20 and displays it (see FIGS. 9 and 10). Further, the diagnosis result output unit 242 may transmit the diagnosis result of the communication quality diagnosis unit 241 to the communication interface 22 or another device connected via an interface different from the communication interface 22 (not shown).

As described above, in the air conditioning system 1 according to the embodiment of the present invention, each air conditioner 3 detects a waveform feature amount when a control command is received from another air conditioner 3, and the detected waveform feature amount and the said waveform feature amount. The measurement data associated with the device ID of the air conditioner 3 of the communication partner is stored in the waveform feature amount table 321. Then, each air conditioner 3 transmits the communication quality data in which the contents stored in the waveform feature amount table 321 are stored to the centralized monitoring device 2 at a predetermined timing (for example, periodically). Therefore, the centralized monitoring device 2 can easily collect data related to the communication quality between the air conditioners 3.

Further, the centralized monitoring device 2 diagnoses the communication quality based on the communication quality data by each air conditioner 3, that is, one or a plurality of waveform features detected by each air conditioner 3. As a result, not only a communication abnormality but also a state in which communication is possible but not good can be detected, so that the user can grasp the air conditioner 3 to be careful in advance and take appropriate preliminary measures.

Further, since the centralized monitoring device 2 and the other air conditioner 3 can be indirectly communicated with each other, it is not possible to directly communicate with the centralized monitoring device 2 due to a communication failure due to a wiring error, disconnection, or the like. However, each air conditioner 3 can notify the centralized monitoring device 2 of the communication quality data.

The present invention is not limited to the above embodiment, and various modifications can be made without departing from the gist of the present invention.

For example, each air conditioner 3 stores in the secondary storage device 32 data in which the number of retransmissions until the control command is normally received on the communication partner side and the device ID of the communication partner air conditioner 3 are associated with each other. It may be saved in the retransmission number management table (not shown), and such data may be included in the communication quality data. In this way, the centralized monitoring device 2 makes it easy to identify the air conditioner 3 whose communication quality is unstable. In addition, each air conditioner 3 secondarily stores data in which a transmission error occurs even after being retransmitted a certain number of times and the device ID of the air conditioner 3 of the communication partner is associated with each other. It may be stored in a transmission error management table (not shown) stored in the device 32, and such data may be included in the communication quality data. In this way, the centralized monitoring device 2 can easily identify the air conditioner 3 having poor communication quality.

Further, any one of the air conditioners 3 may collect communication quality data from the other one or a plurality of air conditioners 3 to diagnose the communication quality in the air conditioning system 1.

Further, in each air conditioner 3, the relay destination search unit 342 can communicate with the own unit if there is no other air conditioner 3 capable of communicating with the own unit and there is no air conditioner 3 capable of directly communicating with the centralized monitoring device 2. Another air conditioner 3 may be searched for an air conditioner 3 capable of indirectly communicating with the centralized monitoring device 2. In this case, when the air conditioner 3 that cannot directly communicate with the centralized monitoring device 2 but can perform indirect communication receives the communication quality data from another air conditioner 3, the air conditioner 3 can directly communicate the communication quality data with the centralized monitoring device 2. Transfer to the air conditioner 3.

In the above embodiment, in each air conditioner 3, the control unit 34 executes the communication quality measurement program 320 stored in the secondary storage device 32, so that each functional unit of the control unit 34 (see FIG. 4). Has been realized. Further, in the centralized monitoring device 2, each functional unit (see FIG. 8) of the control unit 24 is realized by executing the communication quality diagnosis program 230 stored in the secondary storage device 23 by the control unit 24. ..

However, all or part of the functional units of the control unit 34 of each air conditioner 3 may be realized by dedicated hardware. Similarly, all or part of the functional units of the control unit 24 of the centralized monitoring device 2 may be realized by dedicated hardware. Dedicated hardware is, for example, a single circuit, a composite circuit, a programmed processor, an ASIC (Application Specific Integrated Circuit), an FPGA (Field-Programmable Gate Array), or a combination thereof.

Further, in the above embodiment, the communication quality diagnosis program 230 executed by the control unit 24 of the centralized monitoring device 2 includes a CD-ROM (Compact Disc Read Only Memory), a DVD (Digital Versatile Disc), and a magneto-optical disc (Magneto-). It is also possible to store and distribute it in a computer-readable recording medium such as an optical disc), a USB (Universal Serial Bus) memory, a memory card, or an HDD. Then, by installing the communication quality diagnosis program 230 distributed in this way on a specific or general-purpose computer, it is possible to make the computer function as the centralized monitoring device 2 in the above embodiment.

Further, the communication quality diagnosis program 230 may be stored in a disk device or the like owned by another server on the Internet so that the communication quality diagnosis program 230 can be downloaded from the server to the centralized monitoring device 2.

The present invention is capable of various embodiments and modifications without departing from the broad spirit and scope. Moreover, the above-described embodiment is for explaining the present invention, and does not limit the scope of the present invention. That is, the scope of the present invention is indicated not by the embodiment but by the claims. Then, various modifications made within the scope of the claims and the equivalent meaning of the invention are considered to be within the scope of the present invention.

1 air conditioning system, 2 centralized monitoring device, 3 air conditioner, 4 communication lines, 20 displays, 21 input devices, 22, 30 communication interfaces, 23, 32 secondary storage devices, 24, 34 controls, 31 main units, 33 waveforms. Acquisition unit, 230 communication quality diagnosis program, 231 collection data table, 240 communication quality data collection unit, 241 communication quality diagnosis unit, 242 diagnosis result output unit, 320 communication quality measurement program, 321 waveform feature table, 340 waveform feature detection Unit, 341 Data notification unit, 342 Relay destination search unit, 343 Data transmission / reception unit, 344 Air conditioning control unit

Claims (7)

Command receiving means for receiving control commands from other air conditioners,
Waveform feature detection means that detects the waveform feature of the communication signal in the received control command and stores the waveform feature data in which the detected waveform feature is associated with the identification information of the other air conditioner in a data table. When,
A waveform feature transmission means for transmitting waveform feature data stored in the data table to a centralized monitoring device at a predetermined timing, and a waveform feature transmission means.
Waveform feature receiving means for receiving waveform feature data from other air conditioners, and
A relay destination search means for searching for another air conditioner capable of directly communicating with the centralized monitoring device is provided.
The waveform feature amount transmitting means is
When it is not possible to directly communicate with the centralized monitoring device, the waveform feature data stored in the data table is transmitted to another air conditioner searched by the relay destination search means.
When the waveform feature data from another air conditioner is received by the waveform feature receiving means, the waveform feature data is transferred to the centralized monitoring device.
If there is no other air conditioner that cannot directly communicate with the centralized monitoring device and can directly communicate with the centralized monitoring device, error notification is performed by at least one of light emission, sound output, and message display. To do, air conditioner. Command receiving means for receiving control commands from other air conditioners,
Waveform feature detection means that detects the waveform feature of the communication signal in the received control command and stores the waveform feature data in which the detected waveform feature is associated with the identification information of the other air conditioner in a data table. When,
A waveform feature transmission means for transmitting waveform feature data stored in the data table to a centralized monitoring device at a predetermined timing, and a waveform feature transmission means.
Waveform feature receiving means for receiving waveform feature data from other air conditioners, and
A relay destination search means for searching for another air conditioner capable of directly communicating with the centralized monitoring device, and searching for another air conditioner capable of indirectly communicating with the centralized monitoring device when there is no corresponding air conditioner. With
The waveform feature amount transmitting means is
When it is not possible to directly communicate with the centralized monitoring device, the waveform feature data stored in the data table is transmitted to another air conditioner searched by the relay destination search means.
An air conditioner that transfers the waveform feature data to the centralized monitoring device or another air conditioner when the waveform feature data from another air conditioner is received by the waveform feature receiving means. The air conditioner according to claim 1 or 2 , wherein the waveform feature amount detecting means detects a peak value or a pulse width as the waveform feature amount. A centralized monitoring device and a plurality of air conditioners according to any one of claims 1 to 3 are provided.
The centralized monitoring device is
A communication quality diagnostic means for diagnosing the communication quality between the air conditioners based on the waveform feature data sent from each of the plurality of air conditioners.
An air conditioning system including a diagnosis result output means for outputting the diagnosis result of the communication quality diagnosis means to a display. The communication quality diagnostic means according to claim 4, wherein when the waveform feature amount included in the waveform feature amount data is smaller than a predetermined threshold value, the communication quality diagnosis means determines that the communication quality between the air conditioners is not good. Air conditioning system. Receives control commands from other air conditioners and
The waveform feature amount of the communication signal in the received control command is detected, and the waveform feature amount data in which the detected waveform feature amount is associated with the identification information of the other air conditioner is saved in the data table.
A communication quality measurement method in which waveform feature data stored in the data table is transmitted to a centralized monitoring device at a predetermined timing.
When it is not possible to directly communicate with the centralized monitoring device, another air conditioner capable of directly communicating with the centralized monitoring device is searched for, and the searched other air conditioners are subjected to the waveform feature amount stored in the data table. Send data,
When the waveform feature data from another air conditioner is received, the waveform feature data is transferred to the centralized monitoring device.
If there is no other air conditioner that cannot directly communicate with the centralized monitoring device and can directly communicate with the centralized monitoring device, error notification is performed by at least one of light emission, sound output, and message display. perform, communication quality measurement method. Receives control commands from other air conditioners and
The waveform feature amount of the communication signal in the received control command is detected, and the waveform feature amount data in which the detected waveform feature amount is associated with the identification information of the other air conditioner is saved in the data table.
A communication quality measurement method in which waveform feature data stored in the data table is transmitted to a centralized monitoring device at a predetermined timing.
If it is not possible to communicate directly with the centralized monitoring device, search for another air conditioner that can directly communicate with the centralized monitoring device, and if there is no corresponding air conditioner, it is possible to indirectly communicate with the centralized monitoring device. Search for other air conditioners, and send the waveform feature data stored in the data table to the searched other air conditioners.
A communication quality measurement method in which when waveform feature data from another air conditioner is received, the waveform feature data is transferred to the centralized monitoring device or another air conditioner.

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