JP2012122668A - Air conditioner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air conditioner capable of obtaining information by which the true cause of the occurrence of abnormality can be guessed without depending on the ability of a serviceman at the occurrence of a failure.SOLUTION: The air conditioner 1 includes a controller 12 for performing operation control of the air conditioner 1 based on information from each sensor 8 and operation information from each of devices 9, 10, 11 and performing protection control, abnormality detection, abnormality full stop, and the like thereof. The controller 12 includes a failure true cause guess data acquisition part 13 for computing, from a plurality of preset protection control factors and abnormality detection factors, protection control factors and abnormality detection factors having at least the top first to third occurrence frequencies, ranking and storing the computed factors, and displaying stored information at any time.

Description

  The present invention relates to an air conditioner that can acquire data for inferring the true cause when the air conditioner reaches an abnormal total stop due to a failure.

  The air conditioner has various protection functions and abnormality detection functions. And when they operate, the contents are memorized and can be displayed as needed. This is because when the air conditioner breaks down, it is easy for the service person to grasp the cause of the failure and repair can be performed with high accuracy. Patent Document 1 is provided with a protection function that operates when an abnormality occurs and protects the air conditioner, and includes a storage unit composed of a rewritable nonvolatile memory element (EEPROM). In addition, an air conditioner including a controller that writes abnormal data of the activated protection function and reads out the abnormal data from the storage unit is shown.

  Further, in Patent Document 2, an abnormality of the air conditioner is detected or determined as a failure by abnormality detection and stored in a nonvolatile storage means (EEPROM), while the stored abnormality or failure can be displayed. Display method of the air conditioner, and when the operation of the air conditioner is performed within a predetermined time after the air conditioner is turned on, the contents stored in the non-volatile storage means can be displayed on the display unit Is shown.

JP-A-62-280534 JP-A-9-292152

  In general, the usage environment of an air conditioner varies greatly depending on the season and the user. When a failure occurs and the air conditioner reaches an abnormal total stop, a service call is issued. The service person corresponding to this outputs abnormal data from the above-described storage means, determines the cause of the abnormal total stop from the contents, and performs repairs. However, it may be difficult to estimate the true cause of the abnormality.

  In addition, even if a service person performs detailed operation data acquisition after a visit in order to infer the true cause, the operating environment has changed since the abnormality occurred, so the abnormality cannot be reproduced. There is. As a result, repairs ended in coping therapy, and there were cases where the true cause could not be resolved. For this reason, there is a problem that the possibility of abnormal recurrence remains, which may cause a disadvantage to the user.

  The present invention has been made in view of the circumstances as described above, and can provide information that can be used to infer the true cause of an abnormality without depending on the ability of a service person when a failure occurs. An object is to provide an air conditioner.

In the above description and the following description, “protection control”, “abnormality detection”, and “abnormal total stop” are defined as follows.
Protection control: Preventive control to prevent an abnormal state. The compressor speed is reduced or bypass control is performed, but operation is not stopped.
Abnormality detection: When the specified abnormality detection condition is satisfied, the operation is temporarily stopped. However, after a certain time (for example, 3 minutes) has elapsed, the operation is automatically resumed. Abnormal display on the remote controller is not performed.
Abnormal total stop: If the frequency of abnormal detection meets the specified abnormal total stop condition, operation is stopped permanently. Abnormality is displayed on the remote control, etc., and operation does not return unless the user resolves the abnormal condition.

In order to solve the above-described problems, the air conditioner of the present invention employs the following means.
That is, the air conditioner according to the present invention includes a controller that controls the operation of the air conditioner based on information from each sensor and operation information from each device, and performs protection control, abnormality detection, and abnormal total stop. In the air conditioner, the controller calculates a protection control factor and an abnormality detection factor having an occurrence frequency of at least the top one or the third from a plurality of preset protection control factors and abnormality detection factors, It is characterized by having a failure cause inference data acquisition unit that ranks and stores the information and can display the stored information as needed.

  According to the present invention, the operation frequency of the air conditioner is controlled, and the occurrence frequency is selected from a plurality of protection control factors and abnormality detection factors set in advance in the controller that performs the protection control, abnormality detection, and abnormal total stop. Calculates at least the top 1 to 3 protection control factors and anomaly detection factors, ranks and stores them, and provides a failure cause inference data acquisition unit that can display the stored information at any time. Therefore, when an air conditioner reaches an abnormal total stop, the service person must at least have the highest occurrence frequency among the information stored in the air conditioner itself, that is, among a plurality of protection control factors and abnormality detection factors. By displaying the 1st to 3rd information on the display unit etc. and analyzing it, it is possible to guess not only the direct cause of the abnormality but also the true cause of the occurrence of the abnormality The ability. In other words, the true cause of failure is estimated by grasping the types of factors and operating trends, etc. It can be used as a powerful judgment material. Therefore, it is possible to take true cause solutions instead of coping therapy for abnormalities, to prevent recurrence of abnormalities, and to quickly resolve abnormalities at the first visit in response to a service call. it can.

  Furthermore, the air conditioner according to the present invention is the air conditioner according to any one of the above-described air conditioners, wherein the failure cause estimation data acquisition unit has at least a higher occurrence frequency from the plurality of protection control factors and the abnormality detection factors. A calculation unit for calculating the first to third protection control factors and abnormality detection factors, a storage unit comprising nonvolatile storage means for storing the information, and information written in the storage unit is read as needed. And a display unit for displaying the information.

  According to the present invention, the failure cause estimation data acquisition unit calculates a protection control factor and an abnormality detection factor having an occurrence frequency of at least the top 1 to the third from among a plurality of protection control factors and anomaly detection factors. And a display unit for reading and displaying the information written in the storage part as needed. The acquisition unit calculates, from time to time, a protection control factor and an abnormality detection factor with an occurrence frequency of at least 1st to 3rd among a plurality of protection control factors and anomaly detection factors, and ranks them. Then, the data can be written in or read from the storage unit composed of the nonvolatile storage means (EEPROM) and displayed on the display unit. Therefore, each time protection control or abnormality detection is performed, the information can be updated as needed to always store the latest information, which can be used for true cause analysis when an abnormality occurs.

  Furthermore, in the air conditioner of the present invention, in any of the above air conditioners, the failure cause estimation data acquisition unit includes an external output unit for outputting the information to an external data storage device. It is characterized by.

  According to the present invention, since the failure cause inference data acquisition unit includes an external output unit for outputting information to an external data storage device, a personal computer, a dedicated logger is connected to the external output unit. By connecting an external data storage device such as a network, it is possible to appropriately extract and analyze the above information of the air conditioner that has reached an abnormal total stop. Therefore, it is not always necessary to analyze the cause and the cause of the abnormality at the installation site of the air conditioner that has completely stopped abnormally, or to examine countermeasures, and to respond appropriately and promptly at the optimal location. Can do.

  In the air conditioner according to the present invention, in any one of the above-described air conditioners, the storage unit may perform the first protection control factor and the abnormality detection factor after the air conditioner is turned on. In the meantime, it is possible to store billions of information.

  According to the present invention, the storage unit can store the storage information until the first protection control factor and the abnormality detection factor are generated after the air conditioner is turned on. Even when the power supply is reset due to provisional measures, the storage unit consisting of non-volatile storage means (EEPROM) last time until the first protection control factor and abnormality detection factor occurs after the power is turned on. Up to 100 million information can be retained. Therefore, when the air conditioner reaches an abnormal total stop, the generation factor information up to that time can be reliably acquired.

  In the air conditioner of the present invention, in any one of the above-described air conditioners, the calculation unit can store only the information generated for the past 10 times from the most recently generated protection control factor and abnormality detection factor. It is characterized by.

  According to the present invention, since the calculation unit can store only the information for the past 10 occurrences from the most recently generated protection control factor and abnormality detection factor, the latest 10 occurrences from the latest occurrence can be stored. Only the cause of abnormality can be stored. In other words, since old information whose generation time is too far away may have a low relevance to the factor that caused the abnormal total stop, only new information is stored. Therefore, more accurate analysis can be performed based on the latest information with high relevance, and the memory capacity to be used can be saved as compared with the one that records all generated information.

  According to the present invention, when an air conditioner reaches an abnormal total stop, the service person has at least the occurrence frequency of information stored in the air conditioner itself, that is, a plurality of protection control factors and abnormality detection factors. By displaying the information of the top 1 to 3 on the display unit and analyzing the information, it is possible to infer not only the direct cause of the abnormality but also the true cause of the occurrence of the abnormality. In other words, the true cause of the failure is estimated by grasping the types of factors and operating trends, etc. Because it can be used as a powerful judgment material, it is possible to take a true cause solution rather than coping therapy for the abnormality, prevent the recurrence of the abnormality, and at the first time responding to the service call An early resolution of abnormalities can be achieved through a visit.

1 is a schematic configuration diagram of an air conditioner according to an embodiment of the present invention. It is a flowchart figure of the data acquisition by the failure cause estimation data acquisition part of the air conditioner shown in FIG. It is explanatory drawing of the content and number of a protection control status set to the failure cause estimation data acquisition part of the air conditioner shown in FIG. It is explanatory drawing of the content and number of a compressor stop factor (comp stop factor) by the abnormality set to the failure true cause estimation data acquisition part of the air conditioner shown in FIG. It is explanatory drawing of the sample 1 which estimates a failure factor from the acquisition information by the failure cause estimation data acquisition part of the air conditioner shown in FIG. It is explanatory drawing of the sample 2 which estimates a failure factor from the acquisition information by the failure cause estimation data acquisition part of the air conditioner shown in FIG.

Hereinafter, an embodiment of the present invention will be described with reference to FIGS.
FIG. 1 shows a schematic configuration diagram of an air conditioner according to an embodiment of the present invention, and FIG. 2 shows a control flowchart by the failure cause estimation data acquisition unit.
The air conditioner 1 includes an outdoor unit 2, at least one indoor unit 3, and a remote controller 4 connected to the indoor unit 3. The outdoor unit 2 and the indoor unit 3 are connected through a refrigerant pipe (not shown), and the outdoor unit 2, the indoor unit 3, and the remote controller 4 are connected through a communication line 5.

  The remote controller 4 includes a display unit 6 including an abnormal display unit and an operation unit 7 including an abnormal display erasing unit. The outdoor unit 2 operates the air conditioner 1 based on information from each sensor 8 such as a pressure sensor and a temperature sensor, and operation information from each device such as the inverter 9, fan motor 10, and other external input means 11. The outdoor controller 12 etc. which perform the control control of the content mentioned later, abnormality detection, and abnormal total stop are provided while controlling.

  Furthermore, the air conditioner 1 is equipped with a number of functions for protecting and controlling the air conditioner 1 and detecting an abnormality based on information from each sensor 8, operation information from each device 9 to 11, and the like. . FIG. 3 shows an example of the status of protection control performed in the air conditioner 1 and a status number corresponding to the status. After the air conditioner 1 is turned on after the power is turned on, if any of the protection controls classified by the “protection control status” shown in FIG. The status number is displayed on the controller 12 side.

  For example, as protection control, when “high pressure (HP) protection control” in which the high pressure (HP) increases, the detected value of the high pressure sensor exceeds the set value and the rotation speed of the compressor is reduced, the status number 1 Will be recorded. In the protection control shown in FIG. 3, when a plurality of protection controls are simultaneously established, the protection control number having a larger number is displayed as a number.

  FIG. 4 shows an example of a compressor (comp) stop factor due to an abnormality and a corresponding factor number as an example of the abnormality detection control. After the air conditioner 1 is turned on after the power is turned on, the compressor is temporarily stopped due to any one of the comp stop factors classified as “Comp stop factors” shown in FIG. If it is, the factor number is displayed on the outdoor controller 12 side.

  For example, as a comp stop factor, when the compressor is temporarily stopped due to HP abnormality (high pressure abnormality), the factor number 20 is recorded. This comp stop factor indicates the most recent abnormal comp stop or special control stop factor (excluding normal stop) retroactive to the present time, and the number is output until the next comp stop factor occurs. Hold. In addition, when a plurality of comp stop factors are established simultaneously, the number is updated and displayed with the factor that finally solved the abnormal state.

  Further, in the present embodiment, when the air conditioner 1 reaches an abnormal total stop due to a failure (abnormality), acquisition of failure cause estimation data is acquired for acquiring data for facilitating estimation and analysis of the cause. The unit 13 is provided in the outdoor controller 12. The failure cause estimation data acquisition unit 13 includes a calculation unit 14 that performs calculation of output information, a storage unit 15 that includes nonvolatile storage means (EEPROM), a display unit 16 that includes 7 segments, a personal computer, It comprises an external output unit 17 for outputting storage information to an external data storage device 18 such as a dedicated logger or a network by appropriate communication means 19.

  The calculation unit 14 starts operation when the air conditioner 1 is turned on, and when any protection control in the “protection control status” defined in FIG. 3 is activated, or in FIG. When the compressor is temporarily stopped due to any of the defined “compression stop factors”, information on the last 10 occurrences from the newest is stored, and the protection control status for each 10 times is stored. From the comp stop factors, the protection control status and comp stop factors with the highest occurrence frequency are calculated and ranked, written in the storage unit 15 and displayed on the display unit 16. Is.

  In addition, the storage unit 15 composed of non-volatile storage means (EEPROM) receives rank-ordered information from the first to third ranks of the protection control status and the frequency of occurrence of comp stop factors in response to a command from the calculation unit 14. It is written in EEPROM and recorded, and after the air conditioner 1 is turned on, it has a function to hold it until the first protection control factor and abnormality detection factor occur. Can be displayed.

  The display unit 16 displays necessary information on 7 segments according to a command from the calculation unit 14. Similarly, the external output unit can output necessary information to the connected external data storage device 18 according to a command from the calculation unit 14 and appropriately take out the above information from the air conditioner 1 to the outside. It is what you want to do. Note that the abnormality occurrence information can be displayed on the display unit 6 of the remote controller 4.

FIG. 2 shows a flowchart of data acquisition by the above-mentioned failure cause estimation data acquisition unit 13.
When the operation is started, the calculation unit 14 determines whether or not the air conditioner 1 has just been turned on in step S1. In the case of YES, the process proceeds to step S2, and after reading the data from the nonvolatile storage means (EEPROM) of the storage unit 15 (ranked first to third rank factor numbers), the process proceeds to step S3. To do. In the case of NO, the process goes through step S2 and proceeds to step S3.

  In step S3, it is determined whether or not the above-described factor number detection condition has occurred. If YES, the process proceeds to step S4. On the other hand, if NO, the process proceeds to step S9, and the data (information) read from the EEPROM in step S2 is output to the display unit 16 or the like and the process ends. In step S4, it is determined whether or not the occurrence of the factor number detection condition detected in step S3 is the first (first) after power-on. If this is the first time and YES is determined, the process proceeds to step S5, where the above-described EEPROM data is reset and the process proceeds to step S6. On the other hand, if NO is determined, the process proceeds to step S6 through step S5.

  In step S6, the past ten factor numbers are recorded in the RAM from the most recently generated factor number detected in step S3. Thereafter, the process proceeds to step S7, where factor numbers up to the top three are calculated in descending order of occurrence frequency. At this time, if there are less than three cause numbers and no corresponding data exists, a number corresponding to “not applicable” is calculated. Then, the newly calculated factor numbers from 1st to 3rd are written in the nonvolatile storage means (EEPROM) of the storage unit 15 in step S8, and are output to the display unit 16 and the like in step S9. .

  As described above, the failure cause estimation data acquisition unit 13 stores the stored data until the first protection control factor and the comp stop factor are generated after the air conditioner 1 is turned on. (EEPROM) can hold the data, and the data can be output to the data storage device 18 via the display unit 16 or the external output unit 17 at any time. The information stored in the failure cause estimation data acquisition unit 13 is only the latest occurrence information for the past 10 times from the most recently generated protection control factor and comp stop factor.

Based on the above configuration, according to the present embodiment, the following operational effects are obtained.
While the air conditioner 1 is in operation, no abnormality is detected, but the protection control classified as “protection control status” shown in FIG. When the abnormality detection classified as “completion stop factor due to abnormality” is performed, the data for the past 10 times is stored in the failure cause estimation data acquisition unit 13, and the occurrence frequency is the top one. The first to third ranks are rung-written and written in the storage unit 15 comprising nonvolatile storage means (EEPROM), and can be displayed on the display unit 16 or the external data storage device 18 as needed.

  These pieces of information can be held in the storage unit 15 until the first protection control factor and abnormality detection factor occur after the air conditioner 1 is turned on. For this reason, when the air conditioner 1 is abnormally stopped and a service call is made, the service person displays the data stored in the air conditioner 1 at the first visit on the display unit 16 or the external data storage. By outputting to the apparatus 18 and analyzing the data, not only the direct cause of the abnormal total stop but also the true cause can be estimated.

That is, the above-described data can be used for estimation of a failure factor by analyzing, for example, the sample 1 shown in FIG. 5 or the sample 2 shown in FIG.
For sample 1 (see Figure 5)
In Pattern 1, the first place of protection control factor is discharge pipe temperature protection, the second place is low pressure protection, the third place is compression ratio protection, the first place of comp stop factor is discharge pipe temperature abnormality, the second place is low pressure abnormality, 3 The rank is not applicable. In pattern 2, the first place of protection control factor is discharge pipe temperature protection, second place is not applicable, third place is not applicable, first place of comp stop factor is discharge pipe temperature abnormality, second place is not applicable, The third place is not applicable.

In the case of this sample 1, in general,
(1) Possible causes for abnormal discharge pipe temperature include defective discharge pipe temperature sensor, defective liquid bypass valve, defective control board, insufficient amount of refrigerant, short circuit, etc. (2) Possible causes for abnormal low pressure include poor low pressure sensor, Operation valve closing, evaporator side electronic expansion valve closing (operation failure), refrigerant amount shortage, ie (electronic expansion valve, strainer), etc. (3) Possible causes of liquid back abnormality are piping / wiring unmatch, refrigerant overcharge, overheating Defect control failure, liquid bypass circuit failure, supercooling coil circuit failure, compressor dome temperature sensor failure, etc. (4) Insufficient capacity of the heat exchanger on the capacitor side (short circuit, draft obstruction, filter) In other words, fan motor failure, etc.), high-pressure switch wiring disconnected, connector not connected, operation valve closed, high-pressure sensor defective, refrigerant overrun Charge and the like can be considered.

  Based on these predictive factors, by analyzing the data acquired in the sample 1, in the case of pattern 1, “shortage of refrigerant amount” is estimated as the true cause of the occurrence of abnormality. The reason for this is that the compression ratio protection is working, so that the condition that the discharge pipe temperature becomes high is satisfied in the refrigeration cycle, the discharge pipe temperature sensor failure is unlikely, and both the discharge pipe temperature abnormality and the low pressure abnormality are both In this case, it can be estimated that the possibility of “insufficient amount of refrigerant”, which is a cause common to both, is high. On the other hand, in the case of pattern 2, “discharge pipe temperature sensor failure” and “Td cooling liquid bypass valve failure” are estimated as the true cause of the occurrence of the abnormality. The reason is that the discharge pipe temperature protection and the discharge pipe temperature abnormality are established independently, and in this case, a factor that causes the discharge pipe temperature alone is estimated.

In case of sample 2 (see Fig. 6)
In Pattern 1, the protection control factor is the power transistor (powertra) temperature protection, the second is the current safe protection, the third is not applicable, the comp stop factor is the powertra overheat abnormality, and the second is Current cut abnormality, 3rd place is not applicable. Furthermore, in pattern 2, protection control factor No. 1 is current safe protection, No. 2 is not applicable, No. 3 is not applicable, comp stop factor No. 1 is current cut abnormality, No. 2 is compressor start failure, The third place is not applicable.

In the case of this sample 2, in general,
(1) Possible causes due to overheating of power tigers such as power trough failure, para-tra sensor failure, inverter board power supply failure, inverter cooling fan abnormality, etc. (2) Expected causes associated with current cut include compressor failure, refrigerant leakage, power trough failure, inverter board Power failure, etc. (3) Possible causes for compressor start-up failure include power supply voltage failure, refrigerant circuit component failure, inverter board power supply failure, wiring / connector insertion failure, compressor failure, and the like.

  Based on these predictive factors, by analyzing the data acquired in the sample 2, in the case of pattern 1, “powertra failure” is estimated as the true cause of the occurrence of abnormality. The reason for this is that protection control in the refrigeration cycle is not activated, so it is difficult to think of inverter protection due to an increase in air conditioning load. In addition, both powertra overheat abnormality and current cut abnormality are activated. It can be inferred that there is a high possibility of “insufficient powertra” that is the cause of On the other hand, in the case of pattern 2, “compressor failure” is estimated as the true cause of the occurrence of abnormality. The reason is that both the current cut abnormality and the compressor start failure are operating, and in this case, it can be estimated that there is a high possibility of “compressor failure” which is a common cause of both.

  Thus, according to the present embodiment, when the air conditioner 1 reaches an abnormal total stop, the service person can store information stored in the air conditioner 1 itself, that is, a plurality of protection control factors and abnormality detection factors. In the display section 16, the ranked information with the highest occurrence frequency is displayed on the display unit 16, and by analyzing it, not only the direct cause of the abnormality, but also the abnormality control did not lead to protection control In cases such as when an error is detected or when an abnormality is not fully stopped, the cause of the failure is used as a basis for determining the true cause of the failure by grasping the type of the cause and operating tendency. Can also be guessed. Therefore, it is possible to take true cause solutions instead of coping therapy for abnormalities, to prevent recurrence of abnormalities, and to quickly resolve abnormalities at the first visit in response to a service call. it can.

  Further, the failure cause inference data acquisition unit 13, at any time, through the calculation unit 14, from among a plurality of protection control factors and abnormality detection factors, the protection control factor and abnormality detection factor (the occurrence frequency is at least the top three) ( Comp stop factor due to abnormality) can be calculated and written into the storage unit 15 composed of nonvolatile storage means (EEPROM) or read and displayed on the display unit 16. Therefore, each time protection control or abnormality detection is performed, the information can be updated as needed to always store the latest information, which can be used for true cause analysis when an abnormality occurs.

  The failure cause estimation data acquisition unit 13 includes an external output unit 17 for outputting information to an external data storage device 18. For this reason, by connecting an external data storage device 18 such as a personal computer, a dedicated logger, or a network to the external output unit 17, information stored in the air conditioner 1 that has reached an abnormal total stop is appropriately stored outside. Can be removed and analyzed. Therefore, it is not always necessary to analyze the cause or cause of the abnormality at the installation site of the air conditioner 1 that has completely stopped abnormally, or to examine countermeasures, etc., and to deal with the service appropriately and promptly at the optimal location. be able to.

  Furthermore, in the present embodiment, the storage unit 15 can store storage information until the first protection control factor and abnormality detection factor are generated after the air conditioner 1 is powered on. For this reason, even when the power supply is reset as a provisional response when an abnormality occurs, after the power is turned on, until the first protection control factor and abnormality detection factor are generated, the memory consisting of nonvolatile storage means (EEPROM) is recorded. 100 million parts 15 can keep the previous billion information, so when the air conditioner 1 has stopped abnormally, the cause factor information up to that time is reliably acquired from the billion part 15 can do.

  In addition, the calculation unit 14 can store only the information generated for the past 10 times from the most recently generated protection control factor and abnormality detection factor. Therefore, it is possible to store only the latest abnormality occurrence factors for the past 10 times from newly generated ones. In other words, old information whose generation time is too far away is likely to be less relevant to the factor that caused the abnormal total stop, so only new information is stored. Therefore, more accurate analysis can be performed based on the latest information with high relevance, and the memory capacity to be used can be saved as compared with the one that records all generated information.

In addition, this invention is not limited to the invention concerning the said embodiment, In the range which does not deviate from the summary, it can change suitably. For example, in the above-described embodiment, an example of a single unit in which one indoor unit 2 is connected to one outdoor unit 3 has been described. However, for a multi-unit in which a plurality of indoor units 2 are connected in parallel. It goes without saying that can be applied in the same manner.
Further, the above-described “protection control status”, “completion stop factor due to abnormality”, “sample 1”, “sample 2”, etc. are all examples, and are not necessarily limited to those of the above embodiment. Of course.

DESCRIPTION OF SYMBOLS 1 Air conditioner 8 Each sensor 9 Inverter 10 Fan motor 11 Other external input means 12 Outdoor controller 13 Failure cause estimation data acquisition part 14 Calculation part 15 Storage part 16 Display part 17 External output part 18 External data storage device

Claims (5)

In the air conditioner equipped with a controller that performs operation control of the air conditioner based on information from each sensor and operation information from each device, and performs protection control, abnormality detection, and abnormal total stop,
The controller calculates a protection control factor and an abnormality detection factor having the highest occurrence frequency from the plurality of preset protection control factors and abnormality detection factors, and ranks them. An air conditioner comprising a failure cause inference data acquisition unit that can store and display stored information as needed.   The failure cause inference data acquisition unit calculates a protection control factor and an abnormality detection factor having an occurrence frequency of at least the first to third from the plurality of protection control factors and the abnormality detection factor; 2. The storage device according to claim 1, further comprising: a storage unit comprising non-volatile storage means for storing the information; and a display unit for reading and displaying information written in the storage unit as needed. Air conditioner.   The air conditioner according to claim 1 or 2, wherein the failure cause estimation data acquisition unit includes an external output unit for outputting the information to an external data storage device.   3. The storage unit can store storage information until the first protection control factor and an abnormality detection factor are generated after the air conditioner is turned on. Or the air conditioner of 3. The air conditioning according to any one of claims 2 to 4, wherein the arithmetic unit is capable of storing only the information of the last 10 occurrences from the most recently generated protection control factor and abnormality detection factor. Machine.

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