JP2011089751A - Failure diagnosing system of air conditioner - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To suppress generation of abnormality (failure) during a time when an air conditioner is intensively used, and to quickly detect generation of abnormality and signs of the generation of abnormality in order to take an early countermeasure. <P>SOLUTION: A remote monitoring system 10 determines whether conditions of starting test run are satisfied or not. When the system 10 determines the conditions are satisfied, it starts the test run and performs abnormality detection processing or failure prediction processing of an air conditioning system 11-1. If the system 10 detects abnormality or predicts failure, it reports the detection or the prediction. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a failure diagnosis system for an air conditioner, and more particularly to an automation technology for failure diagnosis of an air conditioning system.

  Conventionally, when performing failure diagnosis of an air conditioner, a diagnosis program for failure is operated during a time when the user does not use the air conditioner at night or on holidays, and the compressor operating frequency and the opening of the electronic expansion valve The operation pattern is controlled, and data is collected (see, for example, Patent Document 1).

JP-A-7-217964

  By the way, the time (season) when the use of the air conditioner is concentrated is determined. For example, an air conditioner such as a GHP (Gas Heat Pump) method is intensively used in summer and winter in principle. The period was often dormant.

For this reason, when the use is concentrated, abnormalities (failures) in the air conditioner and responses (failure diagnosis, repair, etc.) to the abnormalities are also concentrated. In addition to the inconvenience that the state continues, there is a problem that the maintenance worker cannot quickly respond to the user's request.
Therefore, an object of the present invention is to suppress the occurrence of abnormalities (failures) at the time when the use of the air conditioner is concentrated, and it is possible to quickly detect abnormalities and signs of occurrence of abnormalities and take early measures It is to provide a failure diagnosis system.

  In order to achieve the above object, the present invention relates to a failure diagnosis system for an air conditioner in which a plurality of indoor units are connected to an outdoor unit, and the outdoor unit and the indoor unit can be controlled for communication. A determination unit that determines whether or not, a control unit that starts a test run and executes an abnormality detection process or a failure prediction process of the air conditioning system when the determination unit determines that the condition is satisfied, In the case where a failure is predicted, a notification unit that notifies the failure is provided.

According to the above configuration, the determination unit determines whether or not the test operation start condition is satisfied, and the control unit starts the test operation when the determination unit determines that the condition is satisfied, and performs an abnormality detection process of the air conditioning system. Alternatively, failure prediction processing is executed.
As a result of these, the notifying unit notifies when an abnormality is detected or a failure is predicted.
Therefore, by performing a trial operation in an intermediate period when the air conditioner is not used, it is possible to make it possible to perform a normal operation when the use is concentrated.

In this case, when an abnormality is detected or a failure is predicted, this may be notified and the test run may be terminated.
According to the above configuration, it is possible to respond quickly without causing an increase in the abnormality due to the detected abnormality or a deterioration in the state in which the failure is detected.

Further, when there is no abnormality detection or failure prediction within a predetermined time, the test operation may be terminated.
According to the above configuration, abnormality detection or failure prediction can be performed without imposing a burden on the air conditioner more than necessary.

Further, the test operation start condition may include that the day of the test operation is between a predetermined test operation start date and an end date and that it is outside a predetermined test operation execution interval.
According to the above configuration, the trial run can be performed during a desired period, the trial run is not repeated more than necessary, and the air conditioning apparatus to be trial run is not subjected to an excessive load, and is environmentally friendly. A fault diagnosis system can be provided.

In addition, the notification unit may be displayed on the remote controller of the indoor unit or displayed on the remote monitoring side connected for communication.
According to the above configuration, it is possible to quickly notify when an abnormality is detected or a failure is predicted.

Further, the control unit may have a plurality of test operation patterns and execute an abnormality detection process or a failure prediction process according to the selected test operation pattern.
According to the above configuration, it is possible to reliably detect an abnormality that occurs in various situations.

  According to the present invention, it is possible to suppress the occurrence of an abnormality (failure) at the time when the use of the air conditioner is concentrated, and to quickly detect the occurrence of an abnormality and the sign of the occurrence of the abnormality and take early measures. There is an effect.

It is a figure which shows schematic structure of the remote monitoring system which concerns on embodiment to which this invention is applied. It is an operation | movement flowchart of embodiment. It is explanatory drawing of an example of the various setting data regarding a test run. It is a process flowchart of a trial run start judgment process. It is a failure prediction process flowchart for predicting the failure by the refrigerant | coolant overfilling at the time of heating. It is a failure prediction process flowchart for predicting a failure due to a refrigerant shortage during cooling. It is a failure prediction process flowchart for predicting the failure by the leak of an indoor expansion valve. It is a process flowchart of a trial run completion | finish judgment process.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a diagram showing a schematic configuration of a remote monitoring system according to an embodiment to which the present invention is applied.
Broadly speaking, the remote monitoring system 10 is connected to a plurality of air conditioning systems 11-1 and 11-2 and the air conditioning system 11 via a wireless communication network 12, and the air conditioning systems 11-1 and 11-2. On the other hand, a remote monitoring center 13 is provided for performing an operation instruction, a reset instruction at the time of abnormality, and the like.

Here, although the structure of the air conditioning systems 11-1 and 11-2 is demonstrated, since the air conditioning systems 11-1 and 11-2 have taken the same structure, the air conditioning system 11-1 is demonstrated.
The air conditioning system 11-1 includes a plurality of GHP type outdoor units 16-1 and 16-2 each having control boards 15-1 and 15-2 each having a communication function, and an outdoor unit 16- by a serial communication cable 17. 1, 16-2 and a plurality of indoor units 19-11, 19-12, 19-13, 19-21, 19-22 to which remote controllers 18-1 to 18-5 are respectively connected; Connected to the control boards 15-1 and 15-2 of the outdoor units 16-1 and 16-2 via the serial communication cable 17, and operates with respect to the remote monitoring center 13 via the wireless antenna 20 and the wireless communication network 12. A remote monitoring adapter 21 for transmitting data, abnormality data, and the like.

In this case, the plurality of indoor units 19-11, 19-12, and 19-13 and the plurality of indoor units 19-21 and 19-22 are handled as separate systems for control. For example, when the air conditioning system 11-1 is installed as a building air conditioning system in which a plurality of tenants are occupying, the indoor units 19-11, 19-12, and 19-13 correspond to one tenant. The indoor units 19-21 and 19-22 are installed in air-conditioned rooms corresponding to other tenants.
The remote monitoring center 13 is connected between a remote monitoring terminal 25 that centrally manages the remote monitoring center 13 and between the remote monitoring terminal 25 and the wireless antenna 26, and a plurality of air conditioning systems 11-1, 11-. And a remote monitoring interface device (I / F) 27 that performs an interface operation with the communication device 2.

  The control boards 15-1 and 15-2 are configured as computers having MPUs, ROMs, RAMs, communication interfaces, and the like, and include outdoor units 16-1 and 16-2 and corresponding indoor units 19-11 and 19-. 12, 19-13, 19-21, 19-22, communication control with the remote monitoring center 13 and control based on an instruction from the remote monitoring center 13 are centrally performed.

  The outdoor units 16-1 and 16-2 are installed outside and are provided with an outdoor refrigerant pipe, and a compressor is disposed in the outdoor refrigerant pipe. An accumulator is disposed on the suction side of the compressor, and a four-way valve is disposed on the discharge side via an oil separator. On the four-way valve side, an outdoor heat exchanger, an outdoor expansion valve, and a dry core are sequentially arranged. Further, an outdoor fan that blows air toward the outdoor heat exchanger is disposed adjacent to the outdoor heat exchanger. The compressor is connected to and driven by a gas engine via a power transmission member such as a V-belt.

  On the other hand, the indoor units 19-11, 19-12, 19-13, 19-21, 19-22 are installed indoors, and indoor refrigerant pipes are arranged in the indoor heat exchangers. In each case, an indoor expansion valve is disposed in the vicinity of the indoor heat exchanger. Furthermore, the indoor heat exchanger is disposed adjacent to indoor fans that send air to these indoor heat exchangers.

And in the outdoor units 16-1 and 16-2 of the air conditioning system 11-1, the cooling operation or the heating operation is set by switching the four-way valve. In other words, when the four-way valve is switched to the cooling side, the outdoor heat exchanger becomes a condenser and the indoor heat exchanger becomes an evaporator to enter a cooling operation state, and each indoor heat exchanger cools the room. Further, during the cooling operation, the respective valve openings of the indoor expansion valves are controlled according to the air conditioning load.
On the other hand, when the four-way valve is switched to the heating side, the indoor heat exchanger becomes a condenser and the outdoor heat exchanger becomes an evaporator to enter a heating operation state, and each indoor heat exchanger heats the room. Further, during the heating operation, the respective valve opening degrees of the outdoor expansion valve and the indoor expansion valve are controlled according to the air conditioning load.

Next, the case of performing remote monitoring of the air conditioning system 11-1 will be described as an example of the normal operation of the remote monitoring system 10 at normal time.
The outdoor units 16-1 and 16-2 constantly monitor their own operation state or the operation state of the indoor units 19-11, 19-12, 19-13, 19-21, and 19-22. Are always collected and notified to the remote monitoring adapter 21.
As a result, the remote monitoring adapter 21 stores operation data during normal operation, and stores abnormal data for minor abnormalities that do not require an emergency when an abnormality occurs.

When the predetermined communication time is reached, the remote monitoring terminal 25 of the remote monitoring center 13 is connected via the wireless antenna 20 and the wireless communication network 12, and the remote monitoring terminal 25 is adapted to operating data and minor abnormal conditions. Send abnormal data.
As a result, the remote monitoring terminal 25 records the operation log and transmits operation instruction data for performing a predetermined operation as necessary to the outdoor units 16-1 and 16-2 or sends an abnormal reset instruction to the outdoor unit. It transmits to the machines 16-1 and 16-2, or performs a charging process for each tenant according to the operation state.

The remote monitoring adapter 21 connects to the remote monitoring terminal 25 of the remote monitoring center 13 via the wireless antenna 20 and the wireless communication network 12 as soon as possible for abnormalities that are urgent and are urgent. Abnormal data corresponding to the abnormal state is transmitted to the remote monitoring terminal 25.
As a result, the remote monitoring terminal 25 records the operation log and transmits operation instruction data including an operation stop instruction to the outdoor units 16-1 and 16-2 in accordance with the abnormal state.

Next, the outline operation at the time of trial operation of the remote monitoring system 10 will be described by taking as an example the case of performing remote monitoring of the air conditioning system 11-1.
In the present embodiment, the test operation means that an abnormality occurs in the air conditioning system that is not used in the intermediate period between summer and winter, which is the use period of the air conditioning system, and the air conditioning system is installed in the next machine to be used. In order to prevent unavailability, this is an operation that is performed in order to determine whether or not normal operation is possible periodically in the intermediate period.
For this reason, in the trial operation, the outdoor unit and the indoor unit are operated as harsh operating situations that cannot be considered in the normal operation, and in principle, the outdoor unit 16 is detected in order to detect abnormalities that are not easily found in the normal operation. -1, 16-2 and indoor units 19-11, 19-12, 19-13, 19-21, 19-22 are driven at the maximum load (full power).

In this case, the control boards 15-1 and 15-2 of the outdoor units 16-1 and 16-2 have a trial run execution schedule (period in which the trial run can be executed, execution time, execution time, trial run operation mode, etc.). Are stored in advance, and the control boards 15-1 and 15-2 execute the trial run in accordance with the trial run execution schedule.
Then, as a result of the trial run, when a failure prediction condition in which an abnormality is detected or an abnormality is predicted to occur soon is satisfied, the remote monitoring adapter 21 is notified as abnormality data or failure prediction data.

As a result, the remote monitoring adapter 21 is connected to the remote monitoring terminal 25 of the remote monitoring center 13 via the wireless antenna 20 and the wireless communication network 12 as soon as possible, and is obtained from the remote monitoring terminal 25 by trial operation. Abnormal data or failure prediction data is transmitted.
The remote monitoring terminal 25 records an operation log and transmits operation instruction data including an operation stop instruction to the outdoor units 16-1 and 16-2 according to an abnormal state or a failure prediction state.

If the result of the test run is normal, the remote monitoring adapter 21 is notified of the fact as the test run normal end data, and the remote monitoring adapter 21 transmits the radio antenna 20 and the radio communication network 12 as soon as possible. Thus, the remote monitoring terminal 25 of the remote monitoring center 13 is connected, and the test run normal end data is transmitted to the remote monitoring terminal 25.
Therefore, by performing the trial run in the intermediate period periodically according to the execution schedule, it is possible to quickly find and deal with a failure or the like, and when to actually use the air conditioning systems 11-1 and 11-2 ( In summer and winter), it is possible to always maintain a normal operation state.

Next, the operation of the embodiment will be described. In the following description, it is assumed that the control board 15-1 of the outdoor unit 16-1 controls the trial operation.
FIG. 2 is an operation flowchart of the embodiment.
First, the MPU of the control board 15-1 acquires various setting data related to the trial operation with reference to the ROM (step S11).

FIG. 3 is an explanatory diagram of an example of various setting data related to the trial run.
In the present embodiment, a plurality of test run patterns are determined, and each test run pattern has a different test run execution timing and execution contents (execution time, operation mode, etc.).
For example, the first test run pattern defines conditions for performing a test run in an intermediate period between winter and summer (for example, from April to May), and the second test run pattern includes a summer test and a winter test. It is set so as to determine conditions for performing a trial run in an intermediate period (for example, September to November). For example, “Between April 1 and May 31, once a week for 30 minutes in cooling mode (from midnight onwards)”, “Between September 1 and November 30 “Once a month, 20 minutes operation in the heating mode (from midnight to 2pm)”.

Specifically, the setting data is test operation pattern data TP (x) [x is a test operation pattern number, and is an integer of 1 or more. Hereinafter, the same applies to the trial run start data DS (x), trial run end date data DE (x), trial run interval data DI (x), trial run time data TS (x), trial run duration data TR (x ), Test operation mode setting data MD (x).
Here, the trial operation start part data DS (x) is data indicating the first day of the period in which the trial operation is performed. For example, if the first day of the test run period is April 1, “0401” is designated.

The trial run end date data DE (x) is data indicating the last day of the period during which the trial run is performed. For example, “0531” is designated when the last day of the test run period is May 31st.
The trial operation execution interval days data DI (x) is data indicating the interval days from the previous trial operation when performing the trial operation based on the trial operation pattern data TP (x). For example, the interval days for performing the trial operation is 1 week. In this case, “07” is designated, and the trial run is not performed until the number of days elapsed from the previous trial run is 7 days, that is, until the interval period is exceeded.

The trial operation execution time data TS (x) is data indicating the time at which the trial operation is started when the trial operation is performed. For example, when the trial operation is started at 2:15 am in the 24-hour system, “0215”. Is specified.
The trial run execution time data TR (x) is data that designates the time for performing the trial run in minutes. For example, when the trial run is performed for 30 minutes, “030” is designated.
The test operation mode setting data MD (x) is data for specifying an operation mode at the time of test operation, and cooling or heating is specified.

Note that the test run pattern data TP (x) can be set even if the test run periods partially overlap (or completely match), as long as the actual test run time periods do not overlap, the storage capacity As long as it permits, a plurality of test run pattern data TP (x) can be set.
Next, the MPU of the control board 15-1 determines whether or not a trial operation is currently being performed (step S12).
If it is determined in step S12 that the test run is not currently being performed (step S12; No), a test run start determination process is performed to determine whether or not test run pattern data that needs to be started is present (step S13). .

FIG. 4 is a process flowchart of the test operation start determination process.
First, the MPU of the control board 15-1 sets the parameter i for specifying the test run pattern data to 1 in the initial state (step S31). That is, in the initial state, it is determined whether or not the trial run pattern data TP (1) is to be trial run.
Subsequently, the MPU of the control board 15-1 refers to the calendar and starts from the first day of the period in which the trial operation is performed in which today's date (the date when the trial operation start determination process is performed) is indicated by the trial operation start data DS (1). It is determined whether or not the date is the last day of the period for performing the test run indicated by the test run end date data DE (1) (step S32).

In the determination in step S32, the date between today's date and the last day of the period for performing the trial operation indicated by the trial operation end date data DE (1) from the first day of the period for performing the trial operation indicated by the trial operation start data DS (1). (Step S32; Yes), whether today's date has passed more than the number of days represented by the trial operation implementation day data DI (1) from the previous trial operation implementation date EX (1). A determination is made (step S33).
If it is determined in step S33 that today's date has not passed the number of days represented by the trial operation execution day data DI (1) from the previous trial operation implementation date EX (1), today's trial operation pattern data TP Since it is not the day when the trial run should be performed based on (1), the process proceeds to step S41.

In the determination of step S33, if today's date has passed more than the number of days represented by the trial operation execution interval days data DI (1) from the previous trial operation implementation date EX (1), today's date is included in the trial operation pattern data. Therefore, it is determined whether or not the current time is within the range of the time obtained by adding 1 hour to the trial operation time data TS (1) and the trial operation time data TS (1) (step) S34).
If it is determined in step S34 that the current time is outside the range of the time obtained by adding 1 hour to the trial run time data TS (1) and the trial run time data TS (1) (step S34; No), the current time Since it is not the time when the trial run should be performed, the process proceeds to step S41.

If it is determined in step S34 that the current time is within the range of the test run time data TS (1) and the test run time data TS (1) plus one hour (step S34; Yes), the current time is Since it is time to start the trial operation, it is determined whether or not the indoor unit is in operation (step S35). This is because the trial run cannot be performed when the indoor unit is in operation.
If it is determined in step S35 that the indoor unit is in operation (step S35; Yes), the trial operation cannot be performed, and the process is terminated.

If it is determined in step S35 that the indoor unit is not operating (step S35; No), it is determined whether the trial operation mode setting data MD (1) is cooling or heating (step S36).
In the determination of step S36, when the trial operation mode setting data MD (1) is cooling, the cooling trial operation is started, both the outdoor unit and the indoor unit are operated at the maximum load (full power), and the process proceeds to step S39. .

If it is determined in step S36 that the trial operation mode setting data MD (1) is heating, the heating operation is started, both the outdoor unit and the indoor unit are operated at the maximum load (full power), and the process proceeds to step S39. .
Subsequently, the MPU of the control board 15-1 sets the current trial operation pattern N = 1 (= i) (step S39), and ends the process with the previous execution date data EX (N) = today's date (step S40).

  On the other hand, in the determination of step S32, the date of today is between the first day of the period for performing the trial operation indicated by the trial operation start part data DS (1) and the last day of the period for performing the trial operation indicated by the trial operation end date data DE (1). If the date is not (step S32; No), 1 is added to the parameter i for specifying the test run pattern data (step S41), and whether the parameter i exceeds the set number of test run patterns. That is, it is determined whether or not the determination process has been completed for all the test run pattern data (step S42).

If it is determined in step S42 that the parameter i does not exceed the set number of trial run patterns, it is necessary to perform judgment processing for the remaining trial run pattern data. Therefore, the process proceeds to step S32 again, and so on. Perform the process.
Specifically, when the number of test run pattern data set is three, that is, test run pattern data TP1 to TP3, in the case of parameter i = 1 to 3, all the test run pattern data has been judged. Since there is not, the process is shifted to step S32 again.

If the parameter i exceeds the number of trial run patterns set in step S42, there is no trial run pattern data for which no judgment process has been performed, and the MPU of the control board 15-1 ends the process. .
Specifically, when the number of test run pattern data set is three, that is, test run pattern data TP1 to TP3, when parameter i = 4, the determination is completed for all the test run pattern data. Therefore, the process ends.

On the other hand, if it is determined in step S12 that a trial operation is currently being performed (step S12; Yes), the MPU of the control board 15-1 determines whether or not an abnormality has been detected during the test operation (step S14).
The contents of abnormality detection include, for example, refrigerant overfilling during heating operation, refrigerant shortage during cooling operation, and leakage of the indoor expansion valve.

If an abnormality is detected in the determination of step S14, the MPU of the control board 15-1 displays an abnormality code corresponding to the detected abnormality on the remote control 18-1 to 18-5 (step S15).
In parallel with this, the MPU of the control board 15-1 transmits the same abnormality code as the abnormality code displayed on the remote controllers 18-1 to 18-5 to the remote monitoring adapter 21 (step S16).
As a result, the remote monitoring adapter 21 connects the received abnormal code to the remote monitoring terminal 25 of the remote monitoring center 13 via the wireless antenna 20 and the wireless communication network 12, and the remote monitoring terminal 25 is obtained by trial operation. Abnormal data or failure prediction data is transmitted.

As a result, the maintenance service provider who manages the remote monitoring center 13 takes action.
Further, the MPU of the control board 15-1 will continue to perform the trial operation, and this will place a burden on the outdoor units 16-1, 16-2 and eventually the entire air conditioning system 11-1. The operation of the machines 16-1 and 16-2 is stopped, and the trial operation is ended (step S17).

In step S14, if no abnormality is detected during the trial run (step S14; No), the MPU of the control board 15-1 performs a failure prediction process (step S18).
That is, the MPU of the control board 15-1 is not in a state in which an abnormality is detected, but determines whether or not a situation in which an abnormality may be detected in the near future has been detected.

For example, in the outdoor units 16-1 and 16-2, when the refrigerant is overfilled, the operating pressure is increased in the heating operation. If this becomes excessive, the outlet pressure (high pressure side pressure) of the refrigerant compressor exceeds the abnormal detection pressure (eg, 3.8 MPa), and a “refrigerant high pressure abnormality” is reported. In the case of overfilling that does not come out, the equipment continues to operate, for example, by turning on the refrigerant high / low pressure bypass circuit, reducing the rotation speed of the compressor, or using the stop indoor unit as a refrigerant buffer, etc. It will be.
Naturally, it is not preferable to continue operation in such a state because it is uneconomical in terms of energy and burdens the equipment, so it is not desirable to detect such an abnormality, If a situation where an abnormality may be detected in the near future is detected, it can be inspected and repaired (refrigerant recovery, etc.) before the heating season starts.

Here, a specific example of the failure prediction process will be described.
FIG. 5 is a failure prediction process flowchart for predicting a failure due to refrigerant overcharging during heating. It is assumed that the failure prediction process for predicting a failure due to refrigerant overcharging during heating is continuously performed by interruption processing during a trial operation.
In failure prediction processing for predicting failure due to refrigerant overcharging during heating, the MPU of the control board 15-1 determines whether or not the outdoor units 16-1 and 16-2 are in heating operation (step S51). ).

In step S51, when the outdoor units 16-1 and 16-2 are not in the heating operation, the MPU of the control board 15-1 sets the detection timer Ta because it is not necessary to predict the refrigerant overfill state. Reset is performed (step S58), and the process is terminated.
When the outdoor units 16-1 and 16-2 are in the heating operation in the determination in step S51, the MPU of the control board 15-1 indicates that the outlet pressure (high pressure side pressure) of the refrigerant compressor is the heating refrigerant. It is determined whether or not the pressure is a reference pressure (3.2 MPa in the present embodiment) for predicting a failure due to overfilling (step S52).

If the outlet pressure (high-pressure side pressure) of the refrigerant compressor is less than the discrimination reference pressure for predicting a failure due to refrigerant overcharging during heating in the discrimination of step S52 (step S52; No), the control board 15 Since it is not necessary for the MPU of -1 to predict the refrigerant overfill state, the detection timer Ta is reset (step S58), and the process ends.
Next, in step S52, if the refrigerant compressor outlet pressure (high pressure side pressure) is equal to or higher than the determination reference pressure for predicting a failure due to refrigerant overheating during heating, the MPU of the control board 15-1 is used. Determines whether the indoor / outdoor thermo-on capacity ratio is equal to or greater than a predetermined capacity ratio (60% in the present embodiment) (step S53).

When the indoor / outdoor thermo-on capacity ratio is less than the predetermined capacity ratio (60% in the present embodiment) in the determination in step S53 (step S53; No), it is not necessary to predict the refrigerant overfill state. The MPU of the board 15-1 resets the detection timer Ta (step S58) and ends the process.
Next, in the determination of step S53, when the indoor / outdoor thermo-on capacity ratio is equal to or greater than a predetermined capacity ratio (60% in the present embodiment), the MPU of the control board 15-1 has a predetermined average temperature of the indoor outlet. It is determined whether or not the temperature is equal to or lower than the temperature (38 ° C. in the present embodiment) (step S54).

If it is determined in step S54 that the average temperature of the indoor outlet is lower than the predetermined temperature (step S54; No), there is no need to predict the refrigerant overfill state, so the MPU of the control board 15-1 detects The timer Ta is reset (step S58), and the process ends.
If it is determined in step S54 that the average temperature of the indoor outlet is equal to or higher than the predetermined temperature (step S54; Yes), the MPU of the control board 15-1 satisfies a condition that causes a failure due to refrigerant overcharging during heating. In order to eliminate the case where it is only the case, the count of the detection timer Ta is started (or continued) for determining that the condition leading to the failure due to the refrigerant overcharging during heating is continued in time (step S55). ).

Then, whether the MPU of the control board 15-1 has passed a predetermined time (10 minutes in the present embodiment) while satisfying the condition leading to the failure due to the refrigerant overheating during heating based on the count value of the detection timer Ta It is determined whether or not (step S56).
In the determination of step S56, when the predetermined time has not yet passed while satisfying the conditions leading to the failure due to heating refrigerant overcharging (step S56; No), the failure due to heating refrigerant overcharging is predicted. The failure prediction process is temporarily terminated and the next interrupt process is awaited.

  Moreover, in the determination of step S56, when a predetermined time has passed while satisfying the conditions leading to the failure due to overheating refrigerant during heating (step S56; Yes), the failure due to overheating refrigerant during heating is predicted. Therefore, the failure prediction process for predicting a failure due to overheating of the refrigerant during heating is temporarily ended with the prediction content “refrigerant overfilling”.

FIG. 6 is a failure prediction process flowchart for predicting a failure due to a lack of refrigerant during cooling. In addition, the failure prediction process for predicting a failure due to a refrigerant shortage during cooling is always continuously performed during a test operation by an interrupt process, similar to the failure prediction process for predicting a failure due to refrigerant overcharging during heating. Assume that it is running.
In the failure prediction process for predicting a failure due to a refrigerant shortage during cooling, the MPU of the control board 15-1 determines whether or not the outdoor units 16-1 and 16-2 are in a cooling operation (step S61). .

In step S61, when the outdoor units 16-1 and 16-2 are not in the cooling operation, the MPU of the control board 15-1 resets the detection timer Tb because there is no need to predict the refrigerant shortage state. (Step S69), and the process ends.
If it is determined in step S61 that the outdoor units 16-1 and 16-2 are in the cooling operation, the MPU of the control board 15-1 indicates that the refrigerant outlet pressure (high pressure side pressure) is the cooling refrigerant. It is determined whether or not it is equal to or lower than a determination reference pressure (2.1 MPa in the present embodiment) for predicting a failure due to a shortage (step S62).

If it is determined in step S62 that the outlet pressure (high pressure side pressure) of the refrigerant compressor exceeds the determination reference pressure for predicting a failure due to a refrigerant shortage during cooling (step S62; No), the control board 15 Since it is not necessary for the MPU of -1 to predict the refrigerant shortage state, the detection timer Tb is reset (step S69), and the process ends.
If it is determined in step S62 that the outlet pressure (high-pressure side pressure) of the refrigerant compressor is equal to or lower than a determination reference pressure for predicting a failure due to a refrigerant shortage during cooling (step S62; Yes), the refrigerant compressor It is determined whether or not the inlet pressure (low pressure side pressure) is equal to or lower than a determination reference pressure (0.4 MPa in this embodiment) for predicting a failure due to a refrigerant shortage during cooling (step S63).

If it is determined in step S63 that the refrigerant compressor inlet pressure (low pressure side pressure) exceeds the determination reference pressure for predicting a failure due to a lack of cooling medium (step S63; No), the control board 15 Since it is not necessary for the MPU of -1 to predict the refrigerant shortage state, the detection timer Tb is reset (step S69), and the process ends.
If it is determined in step S63 that the refrigerant compressor inlet pressure (low pressure side pressure) is equal to or lower than a determination reference pressure for predicting a failure due to a lack of refrigerant during cooling (step S63; Yes), the control board 15- The one MPU determines whether the indoor / outdoor thermo-on capacity ratio is equal to or greater than a predetermined capacity ratio (80% in the present embodiment) (step S64).

If the indoor / outdoor thermo-on capacity ratio is less than the predetermined capacity ratio (80% in the present embodiment) in the determination in step S64 (step S64; No), it is not necessary to predict the refrigerant shortage state. The MPU of 15-1 resets the detection timer Tb (step S69) and ends the process.
Next, in step S64, if the indoor / outdoor thermo-on capacity ratio is equal to or greater than a predetermined capacity ratio (80% in this embodiment), the MPU of the control board 15-1 has an average opening degree of the indoor expansion valve. It is determined whether or not the opening is equal to or greater than a predetermined opening (in this embodiment, 90%) (step S65).

In the determination of step S65, when the average opening of the indoor expansion valve is less than the predetermined opening (step S65; No), the MPU of the control board 15-1 does not need to predict the refrigerant shortage state. The detection timer Tb is reset (step S69), and the process ends.
If it is determined in step S65 that the average opening of the indoor expansion valve is equal to or greater than the predetermined opening (step S65; Yes), the MPU of the control board 15-1 happens to have a condition that causes a failure due to a lack of refrigerant during cooling. In order to remove the case where it is only satisfied, the detection timer Tb starts counting (or continues) for determining that the condition leading to the failure due to the lack of refrigerant during cooling is continued in time (step S66). ).

Then, the MPU of the control board 15-1 is based on the count value of the detection timer Tb, and whether or not a predetermined time (10 minutes in the present embodiment) has passed while satisfying the conditions leading to the failure due to the lack of refrigerant during cooling. Is determined (step S67).
In the determination in step S67, when the predetermined time has not yet passed while satisfying the conditions leading to the failure due to the refrigerant shortage during cooling (step S67; No), the failure prediction for predicting the failure due to the refrigerant shortage during cooling. The process is temporarily terminated and the next interrupt process is awaited.

  Further, in the determination of step S67, when a predetermined time has passed while satisfying the conditions leading to the failure due to the lack of cooling refrigerant (step S67; Yes), the failure due to the lack of cooling refrigerant is predicted. The failure prediction process for predicting a failure due to a refrigerant shortage during cooling is temporarily ended with the prediction content “refrigerant shortage”.

FIG. 7 is a failure prediction process flowchart for predicting a failure due to leakage of the indoor expansion valve. In addition, the failure prediction process for predicting a failure due to the leakage of the indoor expansion valve is always performed during the trial operation by an interrupt process, similar to the failure prediction process for predicting a failure due to the refrigerant overheating during heating. It is assumed that it is continuously executed.
In failure prediction processing for predicting failure due to leakage of the indoor expansion valve, the MPU of the control board 15-1 determines whether or not the outdoor units 16-1 and 16-2 are in cooling operation (step S71). ).

If it is determined in step S71 that the outdoor units 16-1 and 16-2 are in the cooling operation, the MPU of the control board 15-1 sets the parameter i for specifying the indoor unit to 1 (step S72). ). Specifically, the indoor unit (i = 1) corresponds to the indoor unit 19-11, the indoor unit (i = 2) corresponds to the indoor unit 19-12, and the indoor unit (i = 3) The indoor unit (i = 4) corresponds to the indoor unit 19-13, the indoor unit (i = 4) corresponds to the indoor unit 19-21, and the indoor unit (i = 5) corresponds to the indoor unit 19-22.
If it is determined in step S71 that the outdoor units 16-1 and 16-2 are not in the cooling operation (step S71; No), the leakage of the indoor expansion valve cannot be detected, so that all the indoor units (i) The detection timer Ts (i) corresponding to is reset (step S81), and the process ends.

Subsequently, the MPU of the control board 15-1 determines whether or not the operation of the indoor unit (i) (in this case, since i = 1, the indoor unit 19-11) is stopped (step S73).
In step S73, if the indoor unit (i) is not stopped, the MPU of the control board 15-1 does not detect the leak of the indoor expansion valve. The corresponding detection timer Ts (i) is reset (step S80), and the process ends.
If it is determined in step S73 that the indoor unit (i) is stopped (step S73; Yes), the MPU of the control board 15-1 only stops operation by chance according to the operation status. In order to remove the case, counting of the detection timer Ts (i) for determining that the operation stop state of the indoor unit (i) is continued in time is started (or continued) (step S74).

Then, the MPU of the control board 15-1 determines the predetermined time (in this embodiment, 10%) while the operation stop state of the indoor unit (i) continues in time based on the count value of the detection timer Ts (i). It is determined whether or not (minute) has elapsed (step S75).
In the determination of step S75, if the predetermined time has not elapsed while the operation stop state of the indoor unit (i) has continued in time (step S75; No), a failure due to leakage of the indoor expansion valve is predicted. Therefore, the failure prediction process is temporarily ended, and the next interrupt process is awaited.
In the determination of step S75, when a predetermined time has elapsed with the operation stop state of the indoor unit (i) continuing in time (step S75; Yes), the inlet of the heat exchanger of the indoor unit (i) (Liquid) It is determined whether or not the temperature E1 (i) is equal to or lower than a temperature obtained by subtracting a predetermined temperature (5 ° C. in the present embodiment) from the air suction temperature Rt (i) of the indoor unit (i) ( Step S76).

In the determination in step S76, the inlet (liquid) temperature E1 (i) of the heat exchanger of the indoor unit (i) is a temperature obtained by subtracting a predetermined temperature from the air suction temperature Rt (i) of the indoor unit (i). If it has exceeded (step S76; No), the failure prediction process for predicting a failure due to the leak of the indoor expansion valve is temporarily terminated and the next interruption process is awaited.
In the determination of step S76, the inlet (liquid) temperature E1 (i) of the heat exchanger of the indoor unit (i) is equal to or lower than the temperature obtained by subtracting a predetermined temperature from the air suction temperature Rt (i) of the indoor unit (i). If this is the case (step S76; Yes), the failure due to the leak of the indoor expansion valve is predicted, so the prediction content is “indoor unit (i) expansion valve leak” (step S77), and the indoor unit is specified. 1 is added to the parameter i (step S78), and it is determined whether or not the parameter i exceeds the number of indoor units, that is, whether or not the determination process has been completed for all the indoor units (step S79). .
If it is determined in step S79 that the parameter i does not exceed the number of indoor units (step S79; No), the process proceeds to step S73 again to perform the process for the next indoor unit. Do.
If the parameter i exceeds the number of indoor units in the determination in step S79, the determination process is completed for all the indoor units, and thus the process ends.

Next, the MPU of the control board 15-1 determines whether or not a failure is predicted during the trial operation (step S19).
If it is determined in step S19 that a failure has been predicted during the trial run (step S19; Yes), the MPU of the control board 15-1 displays “inspection” on the remote controllers 18-1 to 18-5 (step S19). S20) A failure prediction code is transmitted to the remote monitoring adapter 21 (step S16).
As a result, the remote monitoring adapter 21 connects the received abnormal code to the remote monitoring terminal 25 of the remote monitoring center 13 via the wireless antenna 20 and the wireless communication network 12, and the remote monitoring terminal 25 is obtained by trial operation. Abnormal data or failure prediction data is transmitted.

Further, the MPU of the control board 15-1 will continue to perform the trial operation, and this will place a burden on the outdoor units 16-1, 16-2 and eventually the entire air conditioning system 11-1. The operation of the machines 16-1 and 16-2 is stopped, and the trial operation is ended (step S17).
On the other hand, if it is determined in step S19 that no failure has been predicted during the trial run (step S19; No), a trial run end judgment process is performed (step S22).

FIG. 8 is a process flowchart of the test run end determination process. It should be noted that this trial run end determination process is also executed continuously by the interrupt process during the trial run.
First, the MPU of the control board 15-1 determines whether or not the outdoor units 16-1 and 16-2 are in operation by a trial operation (step S91).
If it is determined in step S91 that the outdoor unit is not operating (step S91; No), the process ends.

If it is determined in step S91 that the outdoor unit is in operation (step S91; Yes), the operation time from the start of the test operation is integrated (step S92), and the integrated operation time is the test operation pattern data. It is determined whether or not the test run time data TR (1) corresponding to (1) is equal to or longer than the test run time (step S93).
In the determination in step S93, when the accumulated operation time is less than the test operation execution time of the test operation execution time data TR (1) corresponding to the test operation pattern data (1) (step S93; No), it is scheduled. Since the test run time has not elapsed, the process is temporarily terminated.
In the determination in step S93, when the accumulated operation time exceeds the test operation execution time of the test operation execution time data TR (1) corresponding to the test operation pattern data (1) (step S93; Yes), it is scheduled. Since the trial run time has elapsed, the trial run is terminated and the process is terminated.

  In this way, the trial run is automatically executed according to the trial run execution schedule (corresponding to the setting data related to the trial run shown in FIG. 3), and the result is notified to the remote monitoring center 13. While suppressing the occurrence of abnormalities (failures) at times when the use of air conditioners is concentrated, it is possible to detect the occurrence of abnormalities and detect signs of abnormalities (predicting malfunctions), and take early measures, Benefits can be obtained for both users of air conditioners and providers of maintenance services.

In the above description, the case where the trial run execution schedule is stored in the ROM constituting the control boards 15-1 and 15-2 of the outdoor units 16-1 and 16-2 has been described. It is also possible for the remote monitoring terminal 25 of the monitoring center 13 to manage.
By adopting such a configuration, it is possible to carry out a trial run without making the user (customer) aware of it, and setting of a trial run schedule is easy to understand such as an input device of a personal computer of the remote monitoring center 13. Usability is improved because it can be used.

In addition, compared with the case where the trial run execution schedule is stored in the control boards 15-1 and 15-2, the storage capacity and the like are not limited, so the trial run execution conditions can be set in detail. For example, it is possible to appropriately set such that it is not performed when the remote controls 18-1 to 18-5 are operated, or not performed when the room temperature is xx ° C. or higher.
In addition, when changing the trial run execution schedule for the reason of the user (customer), the person in charge of the remote monitoring center 13 can easily change the setting by telephone or web communication from the user. For example, if the heating start schedule is early on December 1 and it is desired to cancel the subsequent test operation because it is desired to start from November 20, the test board execution schedule is set on the control boards 15-1 and 15-2. In the case of storing, it may be necessary for the service person to make adjustments on site, and it may take time to respond, but when the remote monitoring center 13 handles it, it can be easily handled.

DESCRIPTION OF SYMBOLS 10 Remote monitoring system 11-1, 11-2 Air conditioning system 13 Remote monitoring center 15-1, 15-2 Control board 16-1, 16-2 Outdoor unit 19-11 to 19-13, 19-21, 19- 22 Indoor unit 21 Remote monitoring adapter 25 Remote monitoring terminal TP1 to TP3 Test run pattern data

Claims (6)

In the failure diagnosis system for an air conditioner in which a plurality of indoor units are connected to the outdoor unit and the outdoor unit and the indoor unit can be controlled by communication.
A determination unit for determining whether or not the test operation start condition is satisfied;
When it is determined that the determination unit satisfies the condition, a test operation is started, and a control unit that executes abnormality detection processing or failure prediction processing of the air conditioning system;
A failure diagnosis system for an air conditioner, comprising: a notification unit for notifying abnormality detection or failure prediction.   The abnormality diagnosis system for an air conditioner according to claim 1, wherein when an abnormality is detected or a failure is predicted, the failure is notified and the test operation is terminated.   The failure diagnosis system for an air conditioner according to claim 1 or 2, wherein the test operation is terminated when there is no abnormality detection or failure prediction within a predetermined time.   The test operation start condition includes that the day of the test operation is between a predetermined test operation start date and an end date, and is outside a predetermined test operation execution interval. A fault diagnosis system for an air conditioner according to claim 1.   The failure of the air conditioning apparatus according to any one of claims 1 to 4, wherein the notification unit displays the notification on a remote controller of the indoor unit or displays on a remote monitoring side connected for communication. Diagnostic system.   6. The air conditioner failure diagnosis according to claim 1, wherein the control unit has a plurality of test operation patterns, and executes an abnormality detection process or a failure prediction process according to the selected test operation pattern. system.

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