JP2020082962A - Failure analyzing system and failure analyzing device - Google Patents

Abstract

To provide a failure analyzing system that provides identification of a failure event on the basis of meteorological data in a present position of a vehicle, and to provide a failure analyzing server 40.SOLUTION: A failure analyzing server 30 is a failure analyzing device that identifies a failure event occurring in a refrigeration cycle device 6 installed to a vehicle. The failure analyzing server 30 acquires a detection value of an outside temperature sensor 76b (i.e. sensor acquisition value) and meteorological data indicating outside temperature of the present position of the vehicle and identifies a failure event in accordance with the sensor acquisition value and the meteorological data.SELECTED DRAWING: Figure 1

Description

The present invention relates to a failure analysis system and a failure analysis device.

2. Description of the Related Art Conventionally, an air-conditioning service support device, when receiving operation data of an air conditioner, makes a failure determination based on the operation data (see, for example, Patent Document 1).

The air conditioning service support device obtains a regression prediction value by using a part of the actual measurement value data of the operation data, and compares the regression prediction value with a predetermined actual measurement value data of the operation data to determine a failure and a failure. Part/fault event can be identified. Room temperature, outside air temperature, inverter frequency, indoor fan speed, and outdoor fan speed are used as the measured value data.

JP 2006-023051 A

The air conditioning service support device of Patent Document 1 described above can make a failure determination or the like by comparing the regression prediction value with predetermined measured value data of the operation data.

However, Patent Document 1 does not describe that the failure event is identified based on the meteorological data acquired from the meteorological server that collects the meteorological data.

In view of the above points, an object of the present invention is to provide a failure analysis system and a failure analysis device that are capable of identifying a failure event based on the weather data at the current vehicle position acquired from a weather server. To do.

In order to achieve the above object, the invention according to claim 1 is a failure analysis device for specifying a failure event occurring in a refrigeration cycle device (6) mounted on a vehicle,
A vehicle data acquisition unit (S100, S110) that acquires operation data indicating the operation state of the refrigeration cycle apparatus and current position data indicating the current position of the vehicle;
A weather data acquisition unit (S120, S130) for acquiring weather data of the current position of the vehicle based on the current position data from a weather server (40) that collects weather data indicating weather conditions;
A failure identification unit (S160, S161, S162) that identifies a failure event based on the operation data acquired by the vehicle data acquisition unit and the weather data acquired by the weather data acquisition unit.

Accordingly, it is possible to provide the failure analysis device that realizes the identification of the failure event based on the weather data at the current position of the vehicle acquired from the weather server.

In the invention according to claim 10, in the failure analysis system, a refrigeration cycle device (6) mounted on a vehicle,
An operation data acquisition unit (S100, S110) for acquiring operation data indicating the operation state of the refrigeration cycle apparatus,
A current position acquisition unit (S100, S110) for acquiring current position data indicating the current position of the vehicle,
A weather data acquisition unit (S120, S130) for acquiring the weather data of the current position of the vehicle based on the current position data from the weather server (40) for collecting the weather data;
A failure identifying unit (S160, S161, S162) that identifies a failure event of the refrigeration cycle apparatus based on the operation data and the weather data.

Accordingly, it is possible to provide a failure analysis system that can identify a failure event based on the weather data at the current vehicle position acquired from the weather server.

Note that the reference numerals in parentheses for each means described in this column and in the claims indicate the correspondence with the specific means described in the embodiments described later.

It is a schematic diagram which shows the whole structure of the failure analysis system in 1st Embodiment of this invention. 1 is a side view of an automobile equipped with a vehicle air conditioner that constitutes the failure analysis system of the first embodiment. It is a top view of the vehicle in which the vehicle air conditioner which comprises the failure analysis system of 1st Embodiment is mounted. FIG. 3 is a partially enlarged view showing a plurality of air flow paths in the outdoor heat exchanger of the vehicle air conditioner of the first embodiment. It is a schematic diagram which shows the arrangement|positioning relationship of the outdoor heat exchanger, the vehicle exterior air blower, and the outdoor temperature sensor in the vehicle air conditioner of 1st Embodiment. It is a schematic diagram which shows schematic structure of the refrigerating-cycle apparatus of the vehicle air conditioner of 1st Embodiment. It is a schematic diagram which shows the electric constitution of the refrigeration cycle device of the vehicle air conditioner of 1st Embodiment. It is a flowchart which shows the failure analysis notification process in the failure analysis server of 1st Embodiment. It is a flow chart which shows communication control processing in a communication ECU of a 1st embodiment. It is a flowchart which shows the weather data notification process in the weather server of 1st Embodiment. It is a figure which shows the sensor acquisition value as a detection value of the outdoor temperature sensor of 1st Embodiment, weather data, and the change of the difference C of a sensor acquisition value and weather data. In the first embodiment, when the vertical axis is the difference C and the horizontal axis is the time, it is a diagram showing the differences C1 and C2 that change with the change of time. It is a figure which shows the whole structure of the failure analysis system in 2nd Embodiment of this invention.

Embodiments of the present invention will be described below with reference to the drawings. In the following respective embodiments, the same or equivalent portions are denoted by the same reference numerals in the drawings for the sake of simplifying the description.

(First embodiment)
FIG. 1 shows the overall configuration of the failure analysis system 1 of the first embodiment. The failure analysis system 1 of the present embodiment is a system for analyzing a failure event of an in-vehicle air conditioner 3 mounted on an automobile 2.

Specifically, the failure analysis system 1 includes a communication ECU 10, an ACECU 20, a failure analysis server 30, a weather server 40, and a management server 50. The communication ECU 10 is mounted on the automobile 2 and wirelessly communicates with the base station 4 via the antenna 11. As the vehicle 2, for example, a bus of public transportation is used.

The communication ECU 10, the GPS receiver 12, and the ACECU 20 of the present embodiment are mounted on the automobile 2.

The communication ECU 10 acquires air-conditioning data such as the inside air temperature, the outside air temperature, and the refrigerant pressure from the ACECU 20 and the current position data from the GPS receiver 12, and acquires the acquired data via the antenna 11 and the base station 4 into a failure analysis server. Send to 30.

The GPS receiver 12 calculates the current position of the automobile 2 based on the signals transmitted from each of the plurality of artificial satellites, and transmits the current position data indicating the calculated current position to the communication ECU 10.

The ACECU 20 is composed of a microcomputer and a memory and controls the compressor 74 of the vehicle-mounted air conditioner. The detailed description of the AC ECU 20 and the vehicle-mounted air conditioner 3 will be described later.

The failure analysis server 30 acquires meteorological data from the meteorological server 40, acquires air conditioning data from the ACECU 20, and further identifies a failure event of an outside air blowing system based on the acquired meteorological data, air conditioning data, and the like. Execute the process.

The vehicle outside air blow system of the present embodiment is a system that includes an outside vehicle air blower and an outside vehicle heat exchanger in an in-vehicle air conditioner.

The meteorological server 40 repeatedly collects the meteorological data for each area and forms a database including the meteorological data for each area. The weather server 40 searches the database for weather data for each area in accordance with a request from the failure analysis server 30, and transmits the searched weather data for each area to the failure analysis server 30.

As the meteorological data of this embodiment, data indicating the outside air temperature for each region (that is, the outside air temperature at the current position of the automobile 2) is used.

The management server 50 is a server of a management company that performs maintenance, maintenance, etc. of the automobile 2 (that is, the bus).

The base station 4, the failure analysis server 30, the weather server 40, and the management server 50 of this embodiment are connected to a communication line 5 such as the Internet.

Hereinafter, the vehicle-mounted air conditioner 3 of this embodiment will be described with reference to FIGS. 2, 3, 4, and 5.

The vehicle-mounted air conditioner 3 of this embodiment is arranged above the roof 2a of the vehicle 2. The vehicle-mounted air conditioner 3 includes an outdoor heat exchanger 70, outdoor blowers 70a, 70b, 70c, indoor heat exchangers 71, 72, indoor blowers 71a, 71b, 71c, 72a, 72b, 72c, and a filter 73.

The outdoor heat exchanger 70 exchanges heat between the high-pressure refrigerant discharged from the compressor 74, which will be described later, and the outdoor air blown from the outdoor blowers 70a, 70b, 70c as indicated by the arrow Sa in FIG. The refrigerant is cooled by the air outside the vehicle compartment.

The outdoor blowers 70a, 70b, 70c of the present embodiment are arranged on the side of the Tenchi region improvement side with respect to the outdoor heat exchanger 70.

Specifically, the outdoor heat exchanger 70 includes a distribution tank, a collection tank, a plurality of tubes 70d, and heat exchange fins 70e.

The distribution tank distributes the high pressure refrigerant from the compressor 74 to the plurality of tubes 70d. Each of the plurality of tubes 70d allows the high-pressure refrigerant to flow toward the collecting tank. The collecting tank collects the high-pressure refrigerant flowing through the plurality of tubes 70d, and causes the collected high-pressure refrigerant to flow toward the pressure reducing valve 75 described later.

As shown in FIG. 4, the plurality of tubes 70d are arranged at intervals. The heat exchange fins 70e are arranged between two adjacent tubes 70d among the plurality of tubes 70d. The heat exchange fins 70e are formed in a wavy shape and form a plurality of air flow paths 70f between the two tubes 70d.

In the outdoor heat exchanger 70 configured as described above, the high pressure refrigerant is cooled by heat exchange between the high pressure refrigerant flowing through the plurality of tubes 70d and the vehicle outside air flowing through the plurality of air passages 70f. The heat exchange fins 70e promote heat exchange between the high-pressure refrigerant and the air outside the vehicle compartment.

The indoor heat exchanger 71 cools the vehicle interior air with the low pressure refrigerant by exchanging heat between the vehicle interior air blown from the indoor blowers 71a, 71b, 71c and the low pressure refrigerant passing through the pressure reducing valve 75.

The indoor heat exchanger 72 exchanges heat between the vehicle interior air blown from the indoor blowers 72a, 72b, 72c and the low pressure refrigerant that has passed through the pressure reducing valve 75 to cool the vehicle interior air with the low pressure refrigerant.

The indoor heat exchanger 72 of the present embodiment constitutes an indoor air conditioning unit that is housed in an indoor air conditioning case and cools the airflow blown from the indoor blowers 72a, 72b, 72c and blows it out into the vehicle interior.

The indoor heat exchangers 71 and 72 of this embodiment are arranged in parallel (or in series) with respect to the flow of the low-pressure refrigerant. The filter 73 plays a role of purifying the air flow that flows into the indoor heat exchangers 71 and 72.

As shown in FIG. 6, the outdoor heat exchanger 70, the indoor heat exchangers 71 and 72, the compressor 74, and the pressure reducing valve 75 are connected by a refrigerant pipe to configure the refrigeration cycle device 6 that circulates the refrigerant. The compressor 74 includes a compression mechanism that draws in the refrigerant, compresses it, and discharges it.

As the compressor 74 of the present embodiment, for example, an engine-driven compressor that drives the compression mechanism by the driving force of the traveling engine to suck in the refrigerant, compress it, and discharge it is used. In this case, an electromagnetic clutch is arranged between the traveling engine and the engine-driven compressor.

The electromagnetic clutch connects the running engine and the engine-driven compressor and transmits the driving force of the running engine to the engine-driven compressor, the driving force of the running engine and the engine-driven compressor. Switch between the open state and the open state.

Here, the electromagnetic clutch is controlled by the ACECU 20 to alternately implement the connected state and the separated state. As a result, the amount of high pressure refrigerant discharged from the compressor 74 is adjusted.

The pressure reducing valve 75 is a valve that adjusts an opening degree (hereinafter, referred to as a throttle opening degree) of a refrigerant passage through which the refrigerant flows between the refrigerant outlet of the outdoor heat exchanger 70 and the refrigerant inlets of the indoor heat exchangers 71 and 72. It is the body. As the pressure reducing valve 75 of the present embodiment, a mechanical expansion valve is used whose throttle opening is automatically controlled so that the degree of heating of the refrigerant flowing from the refrigerant outlets of the indoor heat exchangers 71, 72 becomes a predetermined value. ..

The refrigeration cycle device 6 is provided with an inside air temperature sensor 76a, an outside air temperature sensor 76b, a high pressure sensor 76c, a low pressure sensor 76d, and a temperature setting device 76e.

The inside air temperature sensor 76a is a temperature sensor that detects the air temperature in the vehicle interior. The outside air temperature sensor 76b is a temperature sensor that detects the temperature of air outside the vehicle compartment. The outside air temperature sensor 76b is arranged near the outdoor heat exchanger 70. More specifically, the outdoor air temperature sensor 76b is arranged upstream of the outdoor heat exchanger 70 in the air flow direction of the vehicle exterior air.

The outside air temperature sensor 76b of the present embodiment is arranged at a position where heat from the high-pressure refrigerant in the outdoor heat exchanger 70 is transmitted. Therefore, the outside air temperature sensor 76b also serves to detect the temperature of the high-pressure refrigerant inside the outdoor heat exchanger 70 in addition to the temperature of the outside air flowing into the outdoor heat exchanger 70.

The high-pressure sensor 76c is a pressure sensor that detects the pressure of the high-pressure refrigerant between the refrigerant outlet of the compressor 74 and the refrigerant inlet of the pressure reducing valve 75. The high pressure sensor 76c of the present embodiment detects the pressure of the high pressure refrigerant between the refrigerant outlet of the compressor 74 and the refrigerant inlet of the outdoor heat exchanger 70.

The low-pressure sensor 76d is a pressure sensor that detects the pressure of the low-pressure refrigerant between the refrigerant outlet of the pressure reducing valve 75 and the refrigerant inlet of the compressor 74. The low pressure sensor 76d of the present embodiment detects the pressure of the low pressure refrigerant between the refrigerant outlets of the indoor heat exchangers 71 and 72 and the refrigerant inlet of the compressor 74.

The temperature setter 76e is a device that sets a set value Set, which is a target temperature of the air temperature in the vehicle compartment, by a user operation.

Next, the electrical configuration of the refrigeration cycle device 6 of this embodiment will be described with reference to FIG. 7.

The ACECU 20 is an electronic control unit including a memory and a microcomputer. The ACECU 20 calculates the target outlet temperature TAO based on the detected temperature of the outside air temperature sensor 76b, the detected temperature of the inside air temperature sensor 76a, and the set temperature Set. The target outlet temperature TAO is a target outlet temperature that needs to be drawn from the indoor air conditioning unit in order to bring the temperature inside the vehicle compartment close to the set temperature Set.

The ACECU 20 controls the electromagnetic clutch in order to bring the temperature of the air blown from the indoor air conditioning unit into the passenger compartment close to the target outlet temperature TAO, and connects or disconnects between the running engine and the engine-driven compressor. Carry out air conditioning control processing.

As the ACECU 20 performs the air conditioning control process, the refrigerant from the compressor 74 circulates through the outdoor heat exchanger 70, the pressure reducing valve 75, the indoor heat exchangers 71 and 72, and the compressor 74 in this order. Along with this, the indoor temperature becomes close to the set temperature Set. That is, the compressor 74, the outdoor heat exchanger 70, the pressure reducing valve 75, and the indoor heat exchangers 71 and 72 operate so that the indoor temperature approaches the set temperature Set.

In response to a request from the failure analysis server 30, the ACECU 20 of the present embodiment collects and collects air conditioning data such as the current position data of the vehicle, the temperature detected by the inside air temperature sensor 76a, and the pressure detected by the high pressure sensor 76c. It plays a role of transmitting the air conditioning data to the failure analysis server 30.

Next, the control processing of the failure analysis system 1 of this embodiment will be described with reference to FIGS. 8, 9, and 10.

The failure analysis server 30 executes the failure analysis notification processing according to the flowchart of FIG. The ACECU 20 executes the air conditioning data return process according to the flowchart of FIG. The weather server 40 executes the weather data return process according to the flowchart of FIG.

First, the failure analysis server 30 repeatedly executes the failure analysis notification process. The failure analysis server 30 transmits a request signal requesting the air conditioning data and the current position data to the ACECU 20 (step S100).

The transmitted request signal is transmitted to the base station 4 via the communication line 5. The transmitted request signal is transmitted from the base station 4 by wireless communication.

Here, the GPS receiver 12 repeatedly calculates the current position data indicating the current position of the automobile. Further, the ACECU 20 repeatedly collects the detected temperature of the inside air temperature sensor 76a, the detected temperature of the outside air temperature sensor 76b, the detected pressure of the high pressure sensor 76c, and the set temperature Set.

On the other hand, when the communication ECU 10 receives the request signal via the antenna 11, the communication ECU 10 acquires the current position data indicating the current position of the vehicle from the GPS receiver 12 (step 200 in FIG. 9).

In addition to this, the communication ECU 10 acquires the detected temperature of the inside air temperature sensor 76a, the detected temperature of the outside air temperature sensor 76b, the detected pressure of the high pressure sensor 76c, and the set temperature Set via the ACECU 20.

Then, the communication ECU 10 transmits the air-conditioning data including the detected temperature of the inside air temperature sensor 76a, the detected pressure of the high pressure sensor 76c, and the set temperature Set and the current position data from the antenna 11 to the base station 4 (step S210 in FIG. 9). ..

At this time, as the detected temperature of the outside air temperature sensor 76b included in the air conditioning data, the detected temperature of the outside air temperature sensor 76b detected at a plurality of different timings (that is, the operation data, for the determination process of step S160 described later). ) Is used.

When the air conditioning data and the current position data thus transmitted are received by the base station 4, the base station 4 transmits the air conditioning data and the current position data to the failure analysis server 30 via the communication line 5.

The failure analysis server 30 determines whether or not the air conditioning data and the current position data from the communication ECU 10 have been received (step S110 in FIG. 8). After that, when the air conditioning data and the current position data from the communication ECU 10 are not received, the failure analysis server 30 determines NO in step S110 and repeats the determination of step S110.

After that, when the failure analysis server 30 receives the air conditioning data and the current position data from the communication ECU 10, the failure analysis server 30 determines YES in step S110.

Along with this, the failure analysis server 30 transmits a request signal for requesting the meteorological data of the current position of the automobile 2 to the meteorological server 40 based on the current position data from the communication ECU 10.

As the meteorological data of this embodiment, outside temperature data indicating the outside temperature at the current position of the automobile 2 is adopted. As the meteorological data, data indicating the outside air temperature at the current position detected at a plurality of timings is used for the determination processing in step S160 described later.

Next, the weather server 40 determines whether the request signal from the failure analysis server 30 has been received (step S300). Then, if the weather server 40 does not receive the request signal from the failure analysis server 30, it determines NO in step S300 and repeats the determination of step S300.

After that, when the weather server 40 receives the request signal from the failure analysis server 30, if YES is determined in step S300, the weather server 40 searches the database for weather data of the current position of the vehicle (step S310).

Next, the weather server 40 transmits the weather data as a search result in this database to the failure analysis server 30 (step S320 in FIG. 10). The transmitted weather data is sent to the failure analysis server 30 via the communication line 5.

As described above, the failure analysis server 30 acquires the meteorological data, the detected temperature of the inside air temperature sensor 76a, the detected pressure of the outside air temperature sensor 76b, the high pressure sensor 76c, and the set temperature Set.

Then, the failure analysis server 30 analyzes the failure event of the refrigeration cycle device 6 based on the meteorological data, the temperature detected by the inside air temperature sensor 76a, the pressure detected by the high pressure sensor 76c, and the set temperature Set.

First, the failure analysis server 30 obtains |(set temperature Set-indoor temperature)| which is the absolute value of the difference obtained by subtracting the temperature detected by the inside air temperature sensor 76a (hereinafter, also referred to as indoor temperature) from the set temperature Set.

Further, the failure analysis server 30 determines whether or not the calculated |(set temperature Set-indoor temperature)| is greater than or equal to the threshold value A (step S140).

Here, the failure analysis server 30 determines NO in step S140 when |(set temperature Set-indoor temperature)| is less than the threshold value A. Along with this, the failure analysis server 30 identifies that the refrigeration cycle apparatus 6 is performing normal operation (step S141).

On the other hand, when |(set temperature Set-indoor temperature)| is greater than or equal to the threshold value A, the failure analysis server 30 determines YES in step S140. Along with this, the failure analysis server 30 identifies that the temperature control of the vehicle compartment by the refrigeration cycle device 6 is not correct (step S150).

Next, the failure analysis server 30 determines whether the pressure detected by the high pressure sensor 76c is higher than the threshold value B (step S151). At this time, when the pressure detected by the high pressure sensor 76c is less than the threshold value B, the failure analysis server 30 determines NO in step S151.

At this time, the failure analysis server 30 returns to step S100 on the assumption that there is a factor of failure in the refrigeration cycle apparatus 6 other than the outdoor transmission scenery system.

On the other hand, when the pressure detected by the high pressure sensor 76c is equal to or higher than the threshold value B, the failure analysis server 30 determines YES in step S151.

At this time, the failure analysis server 30 identifies that the failure event is one of the following (a), (b) and (c) (step S153).

(A) A state in which the outdoor blowers (referred to as condenser fans in FIG. 8) 70a, 70b, and 70c stop due to a failure, and heat exchange between the high-pressure refrigerant and the vehicle exterior air is blocked in the outdoor heat exchanger 70. Is.

(B) A state in which a plurality of air flow passages 70f of the outdoor heat exchanger (condenser in FIG. 8) are clogged with foreign matter, and heat exchange between the high pressure refrigerant and the vehicle exterior air is obstructed. Is.

(C) The refrigeration cycle device 6 is in an overfilled state by being filled with an excessive amount of refrigerant.

Next, the failure analysis server 30 determines which of the above (a), (b) and (c) the failure event corresponds based on the meteorological data and the temperature detected by the outside air temperature sensor 76b (step S154, S160). Hereinafter, for convenience of description, the temperature detected by the outside air temperature sensor 76b is referred to as a sensor acquisition value.

Here, when the failure event corresponds to either of (a) and (b), the heat exchange between the high-pressure refrigerant and the air outside the vehicle compartment is blocked in the outdoor heat exchanger 70. For this reason, the temperature of the high-pressure refrigerant in the outdoor heat exchanger 70 becomes high, so that heat is transferred from the high-pressure refrigerant in the outdoor heat exchanger 70 to the outside air temperature sensor 76b. As a result, the temperature detected by the outside air temperature sensor 76b rises.

Therefore, the failure analysis server 30 obtains “sensor acquisition value-weather data” (see FIG. 11), which is the difference obtained by subtracting weather data from the sensor acquisition value, and the obtained “sensor acquisition value-weather data” is the threshold D. It is determined whether or not this is the case (step S154). At this time, when the “sensor acquisition value-weather data” is less than the threshold value D, the failure analysis server 30 determines NO in step S154.

In this case, the failure analysis server 30 identifies "(c) the refrigeration cycle device 6 is in an overfilled state of the refrigerant" as the failure event (step S155).

Along with this, the failure analysis server 30 transmits to the management server 50 via the communication line 5 that the amount of the refrigerant filled in the refrigeration cycle device 6 should be reduced as a recommended action (step S170).

This allows the management company to be notified of the recommended action in the case of overfilling the refrigerant.

On the other hand, when the "sensor acquisition value-weather data" is equal to or greater than the threshold value D, the failure analysis server 30 determines YES in step S154. In this case, the failure event corresponds to any one of the following (a) and (b).

Here, the outdoor blowers 70a, 70b, and 70c stop due to a failure, and the temperature of the high-pressure refrigerant in the outdoor heat exchanger 70 rapidly rises with the passage of time. Therefore, as indicated by the graph C1 in FIG. 12, the "sensor acquisition value-weather data" (=difference C) sharply rises with the passage of time.

On the other hand, when the outdoor heat exchanger 70 becomes clogged, the temperature of the high-pressure refrigerant in the outdoor heat exchanger 70 is slightly increased because the heat exchange between the high-pressure refrigerant and the air outside the vehicle compartment occurs in the outdoor heat exchanger 70. Gradually increases with the passage of time. Therefore, as indicated by a graph C1 in FIG. 12, the difference C gradually increases with the passage of time.

Here, hereinafter, for convenience of description, the sensor acquisition value at the timing T among the sensor acquisition values at different timings will be referred to as a sensor acquisition value S(T), and the timing (T+t The sensor acquisition value of) is set as the sensor acquisition value S(T+t).
Of the meteorological data at different timings, the meteorological data at timing T is referred to as meteorological data K(T). Of a plurality of different timing meteorological data, meteorological data at a timing (T+t) is referred to as meteorological data K(T+t). Timing (T+t) is the timing when a predetermined period t has elapsed from timing T.

Here, {sensor acquisition value S(T)-weather data K(T)}=C(T), and {sensor acquisition value S(T+t)-weather data K(T+t)}=C(T+t).

The failure analysis server 30 uses the sensor acquisition value S(T), the sensor acquisition value S(T+t), the meteorological data K(T), the meteorological data K(T+t), and the predetermined value cf to determine the next failure event ( It is determined whether any one of (a) and (b) is applicable.

Here, when the failure analysis server 30 satisfies C(T)<C(T+t) and C(T+t)−C(T)≦predetermined value cf, the difference C (=sensor acquisition value−weather data) is the time. It is determined that the value gradually rises with the passage of, and YES is determined in step S160.

At this time, the failure analysis server 30 specifies that the outdoor heat exchanger 70 is in a clogged state as a failure event (step S161).

Along with this, the failure analysis server 30 transmits to the management server 50 through the communication line 5 as a recommended action to clean the plurality of air flow paths 70f of the outdoor heat exchanger 70 to eliminate the clogging (step S170). ..

On the other hand, the failure analysis server 30 determines that the difference C sharply increases with the passage of time when C(T)<C(T+t) and C(T+t)−C(T)>predetermined value cf are satisfied. In step S160, YES is determined.

This allows the management company to be notified of the recommended action when the outdoor heat exchanger 70 is in the clogged state.

At this time, the failure analysis server 30 identifies that the outdoor blowers 70a, 70b, 70c are stopped due to a failure as a failure event (step S162). Along with this, the failure analysis server 30 transmits to the management server 50 through the communication line 5 as a recommended action to eliminate the failure of the outdoor blowers 70a, 70b, 70c (or replace the outdoor blowers 70a, 70b, 70c). (Step S170).

As a result, it is possible to notify the management company of the recommended action when the outdoor blowers 70a, 70b, 70c fail.

According to the present embodiment described above, the failure analysis server 30 is a failure analysis device that identifies a failure event occurring in the refrigeration cycle device 6 mounted on the vehicle.

The failure analysis server 30 acquires the air conditioning data indicating the detection value (that is, the sensor acquisition value) of the outside air temperature sensor 76b and the current position data indicating the current position of the vehicle, and acquires the weather data for each region. From 40, the weather data indicating the outside temperature of the current position of the vehicle based on the current position data is acquired, and the failure event is specified according to the sensor acquisition value and the weather data.

Here, in the air conditioning service support device described in Patent Document 1, in order to perform a failure determination or the like, corresponding actual measurement value data, that is, sensing data is required, and it is required to add a sensor to the in-vehicle device side. However, a trade-off with the initial cost of the in-vehicle device cannot be avoided.

In addition, the need for failure support is greater for already sold vehicles than for new vehicles, and it is often difficult to add a new sensor to an in-vehicle device that has already been set. Absent.

Even if there is one important abnormality in the outdoor air blower in a bus air conditioner, an abnormality signal from the outdoor blower is indispensable for identifying the failure event/site, but there are many specifications that the abnormality signal is not output in already sold vehicles.

In addition, the visual diagnosis of the filter clogging state is actually performed, but it also leads to an increase in maintenance load. There is also an automatic cleaning guidance technology that uses a timer count, but it does not necessarily fit the actual conditions of clogging.

For example, in the present embodiment, the failure analysis server 30 may specify the failure event by using the actual measurement data of the outside air temperature at the current position of the vehicle instead of the weather data acquired from the weather server 40.

However, in this case, in order to acquire the actual measurement data of the outside air temperature, it is necessary to dispose a new outside air temperature sensor at a position where heat from the high-pressure refrigerant in the outdoor heat exchanger 70 is not transmitted. Therefore, the cost is increased with the addition of the new outside air temperature sensor.

On the other hand, in the present embodiment, the failure analysis server 30 identifies the failure event according to the detected value of the outside air temperature sensor 76b (that is, the sensor acquired value) and the weather data indicating the outside air temperature at the current position of the vehicle. To do.

Specifically, when the “sensor acquisition value-weather data” is less than the threshold value D, the failure analysis server 30 identifies “the refrigeration cycle device 6 is in an overfilled state” as a failure event.

When the variation amount dC of “sensor acquisition value-meteorological data” is less than the predetermined value cf, the failure analysis server 30 determines that the difference C gradually increases with time, and the outdoor heat exchanger 70 is clogged. The state of being specified is identified as a failure event.

When the “sensor acquisition value-weather data” change amount dC is greater than or equal to a predetermined value cf, the failure analysis server 30 determines that the difference C has sharply increased with the passage of time, and the outdoor blowers 70a, 70b, and 70c have a failure. The stop event is specified as a failure event.

As described above, it is possible to provide the failure analysis system 1 and the failure analysis server 40 that realize the identification of the failure event based on the meteorological data at the current position of the vehicle.

In the present embodiment, the failure analysis server 30 sends a countermeasure to be taken in response to the specified failure event to the management server 50 through the communication line 5 as a recommended action in association with the specified failure event.

With this, it is possible to notify the management company of the recommended action corresponding to the failure event.

In the present embodiment, the failure analysis server 30 acquires the outside air temperature at the current position of the automobile 2 as meteorological data instead of actual measurement data and analyzes the failure. Therefore, it is not necessary to add an outside air temperature sensor for measuring the outside air temperature at the current position of the automobile 2 as actual measurement data. As a result, the number of parts can be reduced and the cost can be reduced as compared with the case where the outside air temperature sensor is added.

In the present embodiment, the outside air temperature sensor 76b is used to detect the temperature of the high-pressure refrigerant inside the outdoor heat exchanger 70. Therefore, the number of parts can be reduced and the cost can be reduced as compared with the case where a refrigerant temperature sensor for detecting the temperature of the high-pressure refrigerant in the outdoor heat exchanger 70 is added.

(Second embodiment)
In the first embodiment described above, an example in which the failure analysis server 30 is installed outside the automobile 2 has been described, but instead of this, a failure analysis server 30A that replaces the failure analysis server 30 is arranged in the automobile 2 An embodiment will be described with reference to FIG.

The failure analysis server 30A is composed of an electronic control unit mounted in the automobile 2. Therefore, the failure analysis server 30A communicates with the weather server 40 and the management server 50 via the communication ECU 10 and the communication line 5.

The failure analysis notification process in the failure analysis server 30A is the same as the failure analysis notification process in the failure analysis server 30 of the first embodiment, and therefore its description is omitted.
As described above, similarly to the first embodiment, it is possible to provide the failure analysis system 1 and the failure analysis server 40 that realize the identification of the failure event based on the meteorological data at the current position of the vehicle.

(Other embodiments)
(1) In the first and second embodiments described above, the example in which the failure analysis system 1 is configured by using the bus as the automobile 2 has been described. However, instead of this, the failure analysis system 1 is performed by using a vehicle other than the bus. The analysis system 1 may be configured.

(2) In practicing the present invention, in the first and second embodiments, the failure analysis system 1 may be configured by using a vehicle already on the market.

(3) In the first and second embodiments, an example in which an engine-driven compressor that drives a compression mechanism by a running engine is used as the compressor 74 has been described, but instead of this, a compressor is used. As 74, an electric compressor in which a compression mechanism is driven by an electric motor may be used.

In this case, the amount of refrigerant discharged from the compressor 74 is adjusted by the AC ECU 20 controlling the rotation speed of the electric motor.

(4) In the first and second embodiments, the mechanical expansion in which the throttle opening is automatically controlled so that the heating degree of the refrigerant flowing from the refrigerant outlets of the indoor heat exchangers 71, 72 becomes a predetermined value. The example in which a valve is used has been described.

However, instead of this, as the pressure reducing valve 75, as the pressure reducing valve 75, a valve body whose throttle opening is controlled by an electric actuator may be used. The electric actuator is controlled by the ACECU 20 and the throttle opening is controlled.

(5) In the first and second embodiments, the failure analysis server 30 uses the temperatures detected by various sensors such as the inside air temperature sensor 76a, the outside air temperature sensor 76b, the high pressure sensor 76c, and the low pressure sensor 76d to detect a failure event. The analyzed example was explained.

However, in addition to this, the failure analysis server 30 may analyze the failure event by using the operation mode of the vehicle-mounted air conditioner 3 and the temperatures detected by various sensors.

(6) In the first and second embodiments, the failure analysis server 30 determines whether the “sensor acquisition value-weather data” has risen sharply or gradually with the passage of time. In doing so, you may implement as follows.

When the “sensor acquisition value-weather data” is the difference data, the failure analysis server 30 calculates the difference data at a plurality of timings based on the air conditioning data acquired from the communication ECU 10.

The failure analysis server 30 statistically calculates difference data at a plurality of different timings to determine whether the “sensor acquisition value-weather data” has risen sharply or gradually over time. To do.

As a result, in analyzing the failure event, it is possible to reduce the influence of variations such as weather and other disturbances (for example, the grill opening degree of the blowing grill).

(7) In the above first and second embodiments, the example in which the current position of the automobile 2 is obtained by using the GPS receiver 2 mounted on the automobile 2 has been described. However, instead of this, the position information of the base station with which the communication ECU 10 mounted on the vehicle 2 wirelessly communicates may be the current position of the vehicle 2.

Alternatively, when the communication ECU 10 wirelessly communicates with a plurality of base stations, the current position of the automobile 2 may be obtained between the communication ECU 10 and the plurality of base stations according to wireless communication.

(8) In the first and second embodiments, the failure analysis server 30 has described the example in which the failure analysis of the refrigeration cycle apparatus 6 is performed using the outside air temperature as the weather condition. Instead of this, failure analysis of the refrigeration cycle apparatus 6 may be performed using weather conditions other than the outside temperature (for example, humidity, atmospheric pressure, and solar radiation amount).

(9) In the first and second embodiments, the failure analysis server 30 has described the example in which the failure analysis is performed on the outdoor ventilation system. Instead of this, the failure analysis may be performed on the equipment other than the outdoor air blowing system (for example, the compressor 74) of the refrigeration cycle apparatus 6.
(10) In the first and second embodiments, the failure analysis server 30 has described the example in which the recommended action corresponding to the failure event is transmitted to the management server 50. However, instead of this, the failure analysis server 30 transmits the recommended action corresponding to the failure event to a device other than the management server 50 (for example, a mobile terminal of the driver of the bus, a server of a company operating the bus, or the like). You may.
(11) The failure analysis server 30 determines whether or not the temperature detected by the inside air temperature sensor 76a, the pressure detected by the high pressure sensor 76c, the set temperature Set, and the current position data are received in step S110.
However, instead of this, it may be determined for each data whether or not the data is received. Here, the data indicates any one of the detected temperature of the inside air temperature sensor 76a, the detected pressure of the high pressure sensor 76c, the set temperature Set, and the current position data.

(12) It should be noted that the present invention is not limited to the above-described embodiments, but can be appropriately modified within the scope of the claims. Further, the above embodiments are not unrelated to each other, and can be appropriately combined unless a combination is obviously impossible. Further, in each of the above-mentioned embodiments, it goes without saying that the elements constituting the embodiment are not necessarily essential unless explicitly stated as being essential and in principle considered to be essential. Yes. Further, in each of the above-described embodiments, when numerical values such as the number of components of the embodiment, numerical values, amounts, ranges, etc. are referred to, it is clearly limited to a particular number and in principle limited to a specific number. The number is not limited to the specific number, except in the case of being performed. Further, in each of the above-mentioned embodiments, when referring to the shapes of the components and the like, the positional relationship, etc., unless otherwise explicitly stated and in principle, the shape, the positional relationship, etc., the shape thereof, It is not limited to the positional relationship or the like. In addition, in each of the above-described embodiments, when it is described that the vehicle external environment information (for example, the humidity outside the vehicle) is acquired from the sensor, the sensor is abolished and the external environment information is acquired from the server or the cloud outside the vehicle. It is also possible to receive. Alternatively, it is also possible to eliminate the sensor, acquire the related information related to the external environment information from the server or the cloud outside the vehicle, and estimate the external environment information from the acquired related information.

Next, the correspondence between the constituent elements of the first and second embodiments and the claims will be described.

Step S100 and step S110 constitute a vehicle data acquisition unit. Steps S120 and S130 form a meteorological data acquisition unit. Step S154, step S155, step S160, step S161, and step S162 constitute a failure identifying unit.

Step S170 corresponds to the failure notification unit. The inside air temperature determination unit corresponds to step S140, the high pressure determination unit corresponds to step S151, and the outside air temperature determination unit corresponds to step S154. The difference determination unit corresponds to step S160.
(Summary)
According to the first aspect described in part or all of the first and second embodiments and the other embodiments, the failure analysis device detects a failure event occurring in the refrigeration cycle device mounted on the vehicle. Identify.

The failure analysis device includes a vehicle data acquisition unit that acquires operation data indicating an operation state of the refrigeration cycle device and current position data indicating a current position of the vehicle.

The failure analysis device includes a meteorological data acquisition unit that acquires meteorological data of the current position of the vehicle based on the current position data from a meteorological server that collects meteorological data indicating a weather condition.

The failure analysis device includes a failure identification unit that identifies a failure event based on the operation data acquired by the vehicle data acquisition unit and the weather data acquired by the weather data acquisition unit.

According to the second aspect, the failure analysis device includes a failure notification unit that notifies a countermeasure to be taken in response to the failure event identified by the failure identification unit.

Thereby, for example, a vehicle maintenance company or the like can be notified of the countermeasure.

According to the third aspect, the refrigeration cycle apparatus includes a compressor that compresses and discharges the refrigerant, and a blower that blows air outside the vehicle compartment.

The refrigeration cycle device is an external heat exchanger for cooling the high pressure refrigerant by exchanging heat between the high pressure refrigerant discharged from the compressor and the outside air blown by the blower, and the refrigerant from the outside heat exchanger. And a pressure reducing valve for reducing the pressure.

The refrigeration cycle apparatus includes an indoor heat exchanger that cools the vehicle interior air by exchanging heat between the refrigerant decompressed by the pressure reducing valve and the vehicle interior air.

The failure specifying unit specifies a failure event related to the outside-air blowing system including the blower and the outside-cabin heat exchanger.

According to the fourth aspect, the refrigeration cycle apparatus includes an outside air temperature sensor that detects the temperature of the vehicle exterior air flowing through the vehicle exterior heat exchanger.

The outside air temperature sensor is arranged at a position where heat is transferred from the refrigerant inside the vehicle exterior heat exchanger. The operation data acquisition unit acquires the temperature detected by the outside air temperature sensor as operation data indicating the refrigerant temperature inside the vehicle exterior heat exchanger. The weather data acquisition unit acquires the outside temperature at the current position of the vehicle as weather data.

According to the fifth aspect, the outside air temperature sensor is arranged upstream of the vehicle exterior heat exchanger in the flow direction of the vehicle exterior air.
Thus, the outside air temperature sensor can accurately detect the outside air temperature.

According to a sixth aspect, the failure analysis device includes an inside temperature determination unit, a high pressure determination unit, and an outside temperature determination unit.

The refrigeration cycle apparatus includes an inside air temperature sensor that detects a vehicle interior temperature of the vehicle, a pressure sensor that detects the pressure of high-pressure refrigerant discharged from the compressor, and a temperature setting unit in which a set temperature is set by an operator. ..

The compressor, the exterior heat exchanger, the pressure reducing valve, and the interior heat exchanger operate so that the temperature of the vehicle interior air approaches the set temperature.

The vehicle data acquisition unit acquires the pressure detected by the pressure sensor, the temperature detected by the inside air temperature sensor, and the set temperature set by the operator in the temperature setting unit.

The inside air temperature determination unit determines whether or not the absolute value of the temperature difference obtained by subtracting the temperature of the vehicle interior air from the set temperature is larger than the first threshold value.

The high pressure determination unit determines whether the pressure of the high pressure refrigerant is higher than the second threshold value.

When the temperature difference obtained by subtracting the meteorological data from the temperature detected by the outside air temperature sensor is taken as the outside air temperature difference, the outside air temperature determination unit determines whether the outside air temperature difference is higher than the third threshold value.

When the absolute value of the temperature difference is larger than the first threshold value, the inside air temperature determination unit determines, and when the pressure of the high pressure refrigerant is higher than the second threshold value, the high pressure determination unit determines that the outside air temperature difference is less than the third threshold value. When the outside air temperature determination unit determines that there is, the failure identification unit identifies, as a failure event, that the refrigerant amount filled in the refrigeration cycle device is in the overfilled state.

As a result, it is possible to specify that the refrigerant amount filled in the refrigeration cycle device is in the overfilled state as a failure event.

According to a seventh aspect, the failure analysis device includes an inside air temperature determination unit, a high pressure determination unit, an outside air temperature determination unit, and a difference determination unit.

The refrigeration cycle apparatus includes an inside air temperature sensor that detects a vehicle interior temperature of the vehicle, a pressure sensor that detects the pressure of high-pressure refrigerant discharged from the compressor, and a temperature setting unit in which a set temperature is set by an operator. ..

The compressor, the exterior heat exchanger, the pressure reducing valve, and the interior heat exchanger operate so that the temperature of the vehicle interior air approaches the set temperature.

The vehicle data acquisition unit acquires the pressure detected by the pressure sensor, the temperature detected by the inside air temperature sensor, and the set temperature set by the operator in the temperature setting unit.

The inside air temperature determination unit determines whether or not the absolute value of the temperature difference obtained by subtracting the temperature of the vehicle interior air from the set temperature is larger than the first threshold value (A).

The high pressure determination unit determines whether the pressure of the high pressure refrigerant is higher than the second threshold value.

When the temperature difference obtained by subtracting the meteorological data from the temperature detected by the outside air temperature sensor is taken as the outside air temperature difference, the outside air temperature determination unit determines whether the outside air temperature difference is higher than the third threshold value.

The difference determination unit determines whether or not the outside air temperature difference gradually increases with the passage of time.

The exterior heat exchanger has a plurality of air passages through which the outside air flows, and exchanges heat between the outside air and the high-pressure refrigerant flowing through the plurality of air passages.

The inside air temperature determination unit determines that the absolute value of the temperature difference is greater than the first threshold value, the high pressure determination unit determines that the pressure of the high pressure refrigerant is higher than the second threshold value, and the outside air temperature difference is greater than the third threshold value. The outside temperature determination unit determines that the temperature is high, and the difference determination unit determines that the outside temperature difference gradually increases with time. At this time, the failure identifying unit identifies, as a failure event, that the heat exchange between the outside air and the high-pressure refrigerant is obstructed when the plurality of air flow paths in the vehicle exterior heat exchanger are clogged with foreign matter. To do.

As a result, it is possible to specify, as a failure event, that the heat exchange between the vehicle exterior air and the high-pressure refrigerant is obstructed when the plurality of air flow paths of the vehicle exterior heat exchanger are clogged with foreign matter.

According to an eighth aspect, the failure analysis device includes an inside air temperature determination unit, a high pressure determination unit, an outside air temperature determination unit, and a difference determination unit.

The refrigeration cycle device includes an inside air temperature sensor that detects the temperature inside the vehicle compartment, a pressure sensor that detects the pressure of the high-pressure refrigerant discharged from the compressor, and a temperature setting unit in which the set temperature is set by the operator. ..

The compressor, the exterior heat exchanger, the pressure reducing valve, and the interior heat exchanger operate so that the temperature of the vehicle interior air approaches the set temperature.

The vehicle data acquisition unit acquires the pressure detected by the pressure sensor, the temperature detected by the inside air temperature sensor, and the set temperature set by the operator in the temperature setting unit.

The inside air temperature determination unit determines whether or not the absolute value of the temperature difference obtained by subtracting the temperature of the vehicle interior air from the set temperature is larger than the first threshold value.

The high pressure determination unit determines whether the pressure of the high pressure refrigerant is higher than the second threshold value.

When the temperature difference obtained by subtracting the meteorological data from the temperature detected by the outside air temperature sensor is taken as the outside air temperature difference, the outside air temperature determination unit determines whether the outside air temperature difference is higher than the third threshold value.

The difference determination unit determines whether or not the outside air temperature difference sharply increases with the passage of time.

The inside air temperature determination unit determines that the absolute value of the temperature difference is greater than the first threshold value, the high pressure determination unit determines that the pressure of the high pressure refrigerant is higher than the second threshold value, and the outside air temperature difference is greater than the third threshold value. When the outside air temperature determination unit determines that the temperature is high, and when the difference determination unit determines that the outside air temperature difference sharply increases with the passage of time, the failure identification unit notifies that the blower is stopped due to a failure. Identify as a failure event.

As a result, it is possible to specify that the blower is stopped due to a failure as a failure event.

According to a ninth aspect, the operation data acquisition unit, the meteorological data acquisition unit, and the failure identification unit are configured by an electronic control device mounted on the vehicle.

According to a tenth aspect, the failure analysis system includes a refrigeration cycle device mounted on a vehicle, an operation data acquisition unit that acquires operation data indicating an operation state of the refrigeration cycle device, and a current position indicating a current position of the vehicle. The present position acquisition part which acquires position data is provided.

The failure analysis system includes a meteorological data acquisition unit that acquires meteorological data of the current position of the vehicle based on the current position data from a meteorological server that collects meteorological data indicating a weather condition.

The failure analysis system includes a failure identifying unit that identifies a failure event of the refrigeration cycle device based on the operation data and the weather data.

1 Failure analysis system 3 In-vehicle air conditioner 10 Communication ECU
20 AC ECU
30, 30A Failure analysis server 40 Meteorological server 50 Management server 70 Outdoor heat exchanger 71, 72 Indoor heat exchanger 74 Compressor 75 Pressure reducing valve

Claims (10)

A failure analysis device for identifying a failure event occurring in a refrigeration cycle device (6) mounted on a vehicle, comprising:
A vehicle data acquisition unit (S100, S110) that acquires operation data indicating the operation state of the refrigeration cycle apparatus and current position data indicating the current position of the vehicle;
A weather data acquisition unit (S120, S130) for acquiring weather data of the current position of the vehicle based on the current position data from a weather server (40) that collects weather data indicating weather conditions;
A failure identification unit (S154, S155, S160, S161, S162) that identifies the failure event based on the operation data acquired by the vehicle data acquisition unit and the weather data acquired by the weather data acquisition unit. When,
Failure analysis device. The failure analysis device according to claim 1, further comprising: a failure notification unit (S170) that notifies a countermeasure to be implemented in response to the failure event identified by the failure identification unit. The refrigeration cycle apparatus includes a compressor (74) that compresses and discharges a refrigerant, a blower (70a, 70b, 70c) that blows air outside a vehicle, a high-pressure refrigerant that is discharged from the compressor, and a blower that is blown by the blower. A heat exchanger (70) for exchanging heat with the outside air to cool the high-pressure refrigerant, a pressure reducing valve (75) for reducing the pressure of the refrigerant from the heat exchanger outside the vehicle, and the pressure reducing An indoor heat exchanger (71, 72) that cools the vehicle interior air by exchanging heat between the refrigerant decompressed by the valve and the vehicle interior air,
The failure analysis device according to claim 1 or 2, wherein the failure identification unit identifies the failure event related to an outside-air blowing system including the blower and the vehicle exterior heat exchanger. The refrigeration cycle apparatus includes an outside air temperature sensor (76b) that detects a temperature of the outside air of the vehicle that flows into the outside heat exchanger of the vehicle,
The outside air temperature sensor is arranged at a position where heat is transmitted from the refrigerant inside the vehicle exterior heat exchanger,
The operation data acquisition unit acquires the detected temperature of the outside air temperature sensor as the operation data indicating the refrigerant temperature in the vehicle exterior heat exchanger,
The failure analysis device according to claim 3, wherein the weather data acquisition unit acquires the outside air temperature at the current position of the vehicle as the weather data. The failure analysis device according to claim 4, wherein the outside air temperature sensor is arranged upstream of a heat exchanger outside the vehicle interior in a flow direction of the air outside the vehicle interior. An inside temperature determination unit (S140), a high pressure determination unit (S151), and an outside temperature determination unit (S154) are provided,
The refrigeration cycle apparatus includes an inside air temperature sensor (76a) that detects the temperature inside the vehicle compartment, a pressure sensor (76c) that detects the pressure of high-pressure refrigerant discharged from the compressor, and a preset temperature set by an operator. And a temperature setting unit (76e) to be set,
The compressor, the vehicle exterior heat exchanger, the pressure reducing valve, and the indoor heat exchanger are operated so that the temperature of the vehicle interior air approaches the preset temperature.
The vehicle data acquisition unit acquires the detected pressure of the pressure sensor, the detected temperature of the inside air temperature sensor, and the set temperature set by the operator in the temperature setting unit,
The inside air temperature determination unit determines whether or not an absolute value of a temperature difference obtained by subtracting the temperature of the vehicle interior air from the set temperature is larger than a first threshold value (A),
The high-pressure determination unit determines whether the pressure of the high-pressure refrigerant is higher than a second threshold value,
When the temperature difference obtained by subtracting the weather data from the temperature detected by the outside air temperature sensor is the outside air temperature difference, the outside air temperature determination unit determines whether the outside air temperature difference is higher than a third threshold value,
The inside air temperature determination unit determines that the absolute value of the temperature difference is greater than the first threshold value, the high pressure determination unit determines that the pressure of the high pressure refrigerant is higher than the second threshold value, and the outside air temperature. When the outside air temperature determination unit determines that the difference is less than a third threshold value, the failure identification unit identifies, as the failure event, that the amount of refrigerant charged in the refrigeration cycle device is in an overfilled state. Item 5. The failure analysis device according to item 4 or 5. An inside temperature determination unit (S140), a high pressure determination unit (S151), an outside temperature determination unit (S154), and a difference determination unit (S160) are provided,
The refrigeration cycle apparatus includes an inside air temperature sensor (76a) that detects the temperature inside the vehicle compartment, a pressure sensor (76c) that detects the pressure of high-pressure refrigerant discharged from the compressor, and a preset temperature set by an operator. A temperature setting unit (76e) to be set,
The compressor, the vehicle exterior heat exchanger, the pressure reducing valve, and the indoor heat exchanger operate so that the temperature of the vehicle interior air approaches the preset temperature,
The vehicle data acquisition unit acquires the detected pressure of the pressure sensor, the detected temperature of the inside air temperature sensor, and the set temperature set by the operator in the temperature setting unit,
The inside air temperature determination unit determines whether an absolute value of a temperature difference obtained by subtracting the temperature of the vehicle interior air from the set temperature is larger than a first threshold value (A),
The high-pressure determination unit determines whether the pressure of the high-pressure refrigerant is higher than a second threshold value,
In the case where the temperature difference obtained by subtracting the meteorological data from the temperature detected by the outside air temperature sensor is the outside air temperature difference, the outside air temperature determination unit determines whether the outside air temperature difference is higher than a third threshold value,
The difference determination unit determines whether or not the outside air temperature difference gradually increases with time,
The vehicle exterior heat exchanger has a plurality of air flow paths (70f) through which the vehicle air flows, and exchanges heat between the vehicle air and the high-pressure refrigerant that flow in the air channels,
The inside air temperature determination unit determines that the absolute value of the temperature difference is greater than the first threshold value, the high pressure determination unit determines that the pressure of the high pressure refrigerant is higher than the second threshold value, and the outside air temperature. When the outside temperature determination unit determines that the difference is higher than a third threshold value, and when the difference determination unit determines that the outside temperature difference gradually increases with the passage of time, the failure specifying unit Specifies, as the failure event, that heat exchange between the outside air and the high-pressure refrigerant is obstructed in a clogged state in which the plurality of air channels of the vehicle exterior heat exchanger are clogged with foreign matter. The failure analysis device according to claim 4 or 5. An inside temperature determination unit (S140), a high pressure determination unit (S151), an outside temperature determination unit (S154), and a difference determination unit (S160) are provided,
The refrigeration cycle apparatus includes an inside air temperature sensor (76a) that detects the temperature inside the vehicle compartment, a pressure sensor (76c) that detects the pressure of high-pressure refrigerant discharged from the compressor, and a preset temperature set by an operator. A temperature setting unit (76e) to be set,
The compressor, the vehicle exterior heat exchanger, the pressure reducing valve, and the indoor heat exchanger operate so that the temperature of the vehicle interior air approaches the preset temperature,
The vehicle data acquisition unit acquires the detected pressure of the pressure sensor, the detected temperature of the inside air temperature sensor, and the set temperature set by the operator in the temperature setting unit,
The inside air temperature determination unit determines whether an absolute value of a temperature difference obtained by subtracting the temperature of the vehicle interior air from the set temperature is larger than a first threshold value (A),
The high-pressure determination unit determines whether the pressure of the high-pressure refrigerant is higher than a second threshold value,
In the case where the temperature difference obtained by subtracting the meteorological data from the temperature detected by the outside air temperature sensor is the outside air temperature difference, the outside air temperature determination unit determines whether the outside air temperature difference is higher than a third threshold value,
The difference determination unit determines whether or not the outside air temperature difference is rapidly increasing with time,
The inside air temperature determination unit determines that the absolute value of the temperature difference is greater than the first threshold value, the high pressure determination unit determines that the pressure of the high pressure refrigerant is higher than the second threshold value, and the outside air temperature. When the outside temperature determination unit determines that the difference is higher than a third threshold value, and when the difference determination unit determines that the outside temperature difference sharply increases with the passage of time, the failure specifying unit The failure analysis device according to claim 4, wherein the failure event specifies that the blower is stopped due to a failure. The failure analysis device according to claim 1, wherein the operation data acquisition unit, the weather data acquisition unit, and the failure identification unit are configured by an electronic control device mounted on the vehicle. A refrigeration cycle device (6) mounted on the vehicle,
An operation data acquisition unit (S100, S110) for acquiring operation data indicating the operation state of the refrigeration cycle apparatus;
A current position acquisition unit (S100, S110) for acquiring current position data indicating the current position of the vehicle;
A weather data acquisition unit (S120, S130) for acquiring weather data of the current position of the vehicle based on the current position data from a weather server (40) that collects weather data indicating weather conditions;
A failure identifying unit (S154, S155, S160, S161, S162) for identifying a failure event of the refrigeration cycle apparatus based on the operation data and the weather data,
Failure analysis system equipped with.

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