A data acquisition unit acquires temperature data for a plurality of battery packs mounted on different equipment (e.g., electric-powered vehicle) in a predetermined period. A statistical calculation unit calculates, for each battery pack, a statistical value based on a temperature change rate in a plurality of charging periods included in the predetermined period. A determination unit determines a temperature adjustment function of the equipment for which a deviation of the statistical value based on the temperature change rate is equal to or greater than a threshold value to be abnormal.

BACKGROUND

Field of the Invention

The present disclosure relates to an abnormality detection system, an abnormality detection method, and an abnormality detection program for detecting an abnormality of the temperature adjustment function of a battery pack.

Description of the Related Art

In recent years, electric-powered vehicles (EVs, HEVs, and PHEVs) are generally equipped with a temperature adjustment mechanism for the purpose of extending the life of the battery pack, etc. For example, the vehicle is equipped with a heater for heating the cells in the battery pack and a cooler for cooling the cells. It is necessary to diagnose whether these temperature adjustment mechanisms are functioning normally.

A method has been proposed in which a temperature sensor is provided at each of the inlet part and the outlet part of the battery part, and an abnormality of the temperature adjustment system is detected by comparing a difference between detection values and the first threshold value (see, for example, Patent Literature 1). This method requires providing a temperature sensor at the inlet part and the outlet part, which increases the cost.

A method of detecting an abnormality of the cooling system when the temperature of the battery is higher than a predetermined temperature, based on the temperature in the vehicle interior and the temperature of the air cooling the battery has also been proposed (see, for example, Patent Literature 2). In this method, it is necessary to acquire the environmental temperature in the vehicle interior.

A method of diagnosing the temperature adjustment mechanism only from the temperature data for the cells without using the environmental temperature is also conceivable. However, it is difficult to determine whether a change in the temperature data is due to a change in the environmental temperature or a failure of the temperature adjustment mechanism.Patent Literature 1: JP2019-21387Patent Literature 2: JP2004-291721

SUMMARY OF THE INVENTION

The present disclosure addresses the issue described above, and a purpose thereof is to provide a technology capable of diagnosing the temperature adjustment function of a battery at low cost while also suppressing the influence of environmental temperature.

An abnormality detection system according to an embodiment of the present disclosure includes: a data acquisition unit that acquires temperature data for a plurality of battery packs mounted on different equipment in a predetermined period; a statistical calculation unit that calculates, for each battery pack, a statistical value based on a temperature change rate in a plurality of charging periods included in the predetermined period; and a determination unit that determines a temperature adjustment function of the equipment for which a deviation of the statistical value based on the temperature change rate is equal to or greater than a threshold value to be abnormal.

Optional combinations of the aforementioned constituting elements, and implementations of the present disclosure in the form of apparatuses, systems, methods, and computer programs are also useful as embodiments of the present disclosure.

DETAILED DESCRIPTION OF THE INVENTION

FIG.1is a diagram showing a schematic configuration of an electric-powered vehicle3according to the embodiment. In this embodiment, a pure EV not equipped with an internal combustion engine is assumed as the electric-powered vehicle3. The electric-powered vehicle3shown inFIG.1is a rear-wheel-drive (2WD) EV including a pair of front wheels31f, a pair of rear wheels31r, and a motor34as a power source. The pair of front wheels31fare connected by a front wheel axle32f, and the pair of rear wheels31rare connected by a rear wheel axle32r. A transmission33transmits the rotation of the motor34to the rear wheel axle32rat a predetermined conversion ratio. The vehicle may be a front-wheel drive (2WD) or 4WD electric-powered vehicle3.

A power supply system40includes a battery pack41, a management unit42, a cooler43, and a heater44. The battery pack41includes a plurality of cells. A lithium ion battery cell, a nickel hydride battery cell, or the like can be used as the cell. Hereinafter, an example of using a lithium ion battery cell (nominal voltage: 3.6-3.7 V) is assumed in this specification.

The cooler43is a water-cooled or air-cooled cooling mechanism for cooling the cells in the battery pack41. A high temperature state of a cell accelerates deterioration of the cell and leads to the occurrence of an unsafe event. The cooler43operates to cool the cell when, for example, the battery pack41is charged or discharged. Further, the cooler43operates to cool the cell when the temperature of the battery pack41exceeds a preset value (for example, 35° C.-40° C.).

The heater44is a heating mechanism for heating the battery pack41. When a lithium-ion battery is charged at a low temperature, dendritic crystals precipitate on the electrodes, which could cause deterioration or malfunction. For example, the heater44operates to heat the cell in the event that the temperature of the battery pack41falls below a preset value for charging (for example, 0° C.-10° C.) when the battery pack41is charged. Further, the heater44operates to heat the cell in the event that the temperature of the battery pack41falls below a preset value for discharging (for example, −15.0° C.-−5.0° C.) when the battery pack41is discharged.

The management unit42monitors and measures the voltage, current, temperature, and SOC (State Of Charge) of the plurality of cells included in the battery pack41and transmits them to a vehicle control unit30as usage data for the plurality of cells via the vehicle-mounted network. For example, CAN (Controller Area Network) or LIN (Local Interconnect Network) can be used as the vehicle-mounted network.

In EVs, a three-phase AC motor is generally used as the motor34for driving. An inverter35converts a DC power supplied from the battery pack41into an AC power and supplies it to the motor34during power running. During regeneration, the inverter35converts the AC power supplied from the motor34into a DC power and supplies it to the battery pack41. The motor34rotates according to the AC power supplied from the inverter35during power running. During regeneration, the motor34converts the rotational energy caused by deceleration into an AC power and supplies it to the inverter35.

The vehicle control unit30is a vehicle ECU (Electronic Control Unit) that controls the entire electric-powered vehicle3and may be, for example, comprised of an integrated VCM (Vehicle Control Module).

A vehicle speed sensor36generates a pulse signal proportional to the rotational speed of the front wheel axle32for the rear wheel axle32rand transmits the generated pulse signal to the vehicle control unit30. The vehicle control unit30detects the speed of the electric-powered vehicle3based on the pulse signal received from the vehicle speed sensor36.

A wireless communication unit37includes a modem for wirelessly connecting to a network5(seeFIG.2) via an antenna37a, and performs wireless signal process. For example, mobile phone networks (cellular networks), wireless LANs, V2I (Vehicle-to-Infrastructure), V2V (Vehicle-to-Vehicle), ETC (Electronic Toll Collection System) DSRC (Dedicated Short Range Communications) can be used.

The vehicle control unit30can transmit traveling data from the wireless communication unit37to a data server6(seeFIG.2) in real time via the network5while the electric-powered vehicle3is traveling. The traveling data at least includes a vehicle ID, a vehicle speed of the electric-powered vehicle3, and a voltage, current, temperature, and SOC of the plurality of cells included in the battery pack41. The vehicle control unit30periodically (for example, every 10 seconds) samples these data items and transmits them to the data server6as they arise.

It should be noted that the vehicle control unit30may store the traveling data for the electric-powered vehicle3in an internal memory and transmit the traveling data stored in the memory collectively according to a predetermined timing schedule. For example, the vehicle control unit30may collectively transmit the traveling data stored in the memory to an operation management terminal apparatus2(seeFIG.2) provided at a site of a delivery company at the end of the day's business. The operation management terminal apparatus2transmits the traveling data for the plurality of electric-powered vehicles3to the data server6according to a predetermined timing schedule.

Alternatively, the vehicle control unit30may collectively transmit the traveling data stored in the memory to the charger via the charging cable when the battery is charged from the charger provided with a network communication function. The charger transmits the received traveling data to the data server6. This example is useful for the electric-powered vehicle3not equipped with a wireless communication function.

FIG.2is a diagram for illustrating an abnormality detection system1according to the embodiment. The abnormality detection system1according to the embodiment is a system used by at least one delivery company. The abnormality detection system1may, for example, be built on an in-house server provided in an in-house facility of a service provider that provides a service of detecting a failure of the temperature adjustment equipment of the battery pack41mounted on the electric-powered vehicle3or provided in a data center. Alternatively, the abnormality detection system1may be built on a cloud server that is used based on a cloud service. Alternatively, the abnormality detection system1may be built on a plurality of servers distributed at a plurality of sites (data centers, in-house facilities). The plurality of servers may be any of a combination of a plurality of in-house servers, a combination of a plurality of cloud servers, or a combination of an in-house server and a cloud server.

The network5is a general term for communication channels such as the Internet, leased lines, and VPN (Virtual Private Network), and the communication medium and the protocol thereof do not matter. For example, a mobile phone network (cellular network), a wireless LAN, a wired LAN, an optical fiber network, an ADSL network, a CATV network, and the like can be used as the communication medium. For example, TCP (Transmission Control Protocol)/IP (Internet Protocol), UDP (User Datagram Protocol)/IP, Ethernet (registered trademark) and the like can be used as the communication protocol.

The delivery company owns a plurality of electric-powered vehicles3and a plurality of chargers4and uses the plurality of electric-powered vehicles3for delivery business. It should be noted that the electric-powered vehicle3can be charged from a charger other than the charger4provided at a delivery base. The delivery company owns delivery bases for parking the electric-powered vehicle3. The operation management terminal apparatus2is provided in the delivery base. For example, the operation management terminal apparatus2is comprised of a PC. The operation management terminal apparatus2is used to manage a plurality of electric-powered vehicle3belonging to the delivery base.

The operation management terminal apparatus2can access the abnormality detection system1via the network5. Prior to using the abnormality detection system1, the operation manager of the delivery company registers the model numbers of the plurality of electric-powered vehicles3managed by the system, using the operation management terminal apparatus2. The operation management terminal apparatus2acquires the vehicle ID of the registered electric-powered vehicle3from the abnormality detection system1. The operation management terminal apparatus2can acquire a diagnostic result of the temperature adjustment function of the battery pack41mounted on each electric-powered vehicle3from the abnormality detection system1.

In a state where the electric-powered vehicle3is parked at the delivery base, the vehicle control unit30and the operation management terminal apparatus2can exchange data via the network5(for example, wireless LAN), a CAN cable, or the like. The vehicle control unit30and the operation management terminal apparatus2may be configured to exchange data via the network5even while the electric-powered vehicle3is traveling. The operation management terminal apparatus2sets the vehicle ID acquired from the abnormality detection system1in the vehicle control unit30of each electric-powered vehicle3.

The data server6acquires and stores traveling data from the operation management terminal apparatus2or the electric-powered vehicle3. The data server6may be an in-house server provided in the delivery company or the failure detection service provider's own facility or in a data center, or a cloud server used by the delivery company or the failure detection service provider. Further, each delivery company and failure detection service provider may have a data server6.

FIG.3is a diagram illustrating an exemplary configuration of the abnormality detection system1according to the embodiment. The abnormality detection system1includes a processing unit11, a storage unit12, and a communication unit13. The communication unit13is a communication interface (for example, NIC: Network Interface Card) for connecting to the network5by wire or wirelessly.

The processing unit11includes a data acquisition unit111, a charging period data extraction unit112, a statistical calculation unit113, a determination unit114, and a notification unit115. The function of the processing unit11can be realized by cooperation between hardware resources and software resources or by hardware resources alone. Hardware resources such as CPU, ROM, RAM, GPU (Graphics Processing Unit), ASIC (Application Specific Integrated Circuit), FPGA (Field Programmable Gate Array), and other LSIs can be used. Programs such as operating systems and applications can be used as software resources.

The storage unit12is inclusive of a non-volatile recording medium such as a HDD and an SSD and stores various data. The storage unit12includes a model-specific threshold retaining unit121. For each model of the electric-powered vehicle3, the model-specific threshold retaining unit121retains the lower limit threshold value and the upper limit threshold value of the temperature change rate [° C./h] during charging described later. Since the specification of the temperature adjustment equipment mounted on the electric-powered vehicle3differs depending on the model of the electric-powered vehicle3, there is also a difference in temperature change rate during charging. During charging, the temperature basically rises due to the influence of the charging current absent supercooling by the cooler43.

For each model of the electric-powered vehicle3, the failure detection service provider determines a range of temperature change rate during charging in a state where the temperature adjustment function is operating normally, based on actual data or simulation data. The fault detection service provider determines the lower limit threshold and the upper limit threshold value of the temperature change rate during charging by adding a predetermined margin to the range of temperature change rate during charging thus determined.

In the case the vehicle manufacturer publishes the specification of the temperature adjustment equipment, the failure detection service provider may identify the tolerable range of temperature change rate during charging based on the specification and determine the lower limit threshold value and the upper limit threshold value of the temperature change rate during charging.

The data acquisition unit111acquires, from the data server6, battery data for the plurality of battery packs41mounted on the plurality of electric-powered vehicles3in a predetermined period (for example, one month). The battery data in the predetermined period is time series data including at least temperature data and current data. In the case a plurality of temperature sensors are provided in the battery pack41, the maximum measured temperature, the minimum measured temperature, the average temperature between the maximum measured temperature and the minimum measured temperature in the battery pack41, or the average temperature of a plurality of observation points are, for example, used as the temperature data in the battery pack41.

The data acquisition unit111acquires, from the data server6, battery data for the electric-powered vehicle3for which the temperature adjustment function is diagnosed and battery data for a plurality of electric-powered vehicles3of the same model as the diagnosed electric-powered vehicle3. That is, the data acquisition unit111acquires battery data for at least three electric-powered vehicles3of the same model.

The charging period data extraction unit112extracts temperature data in a period, within the predetermined period, during which the duration that the charging current is flowing falls within a preset time range, as temperature data in the charging period. Whether the charging current is flowing can be determined based on the sign and absolute value of current data. The charging period data extraction unit112defines, for example, the preset time range of 50 minutes to 24 hours and extracts temperature data within the range as the temperature data in the charging period. In this example, a data pattern in which charging continues for 24 hours or longer is defined as indicating a data abnormality and is not handled as a charging period.

Further, when the number of temperature data items extracted in each charging period is less than the minimum number of data items, the charging period data extraction unit112does not handle the charging period as a charging period. Given that the battery data is sampled at 10 second intervals, and the minimum duration of the charging period is set to 50 minutes as described above, the minimum number of data items in a charging period is set to (300-α). α denotes a margin. Given that the predetermined period is one month and the electric-powered vehicle3is charged once a day, the number of charging periods extracted from the predetermined period will be approximately 30.

The statistical calculation unit113calculates, for each battery pack41of the electric-powered vehicle3, a statistical value based on the temperature change rate in a plurality of charging periods included in the predetermined period. The temperature change rate in each charging period can be determined by dividing the temperature change value of each charging period, which is based on the temperature data at the beginning and end of each charging period, by the duration of the charging period. An average, a median, or a mode can be used as the statistical value based on the temperature change rate in the plurality of charging periods. In this embodiment, an example using an average value is assumed.

For each battery pack41of the electric-powered vehicle3, the statistical calculation unit113averages the temperature change rates in the plurality of charging periods included in the predetermined period to calculate an average temperature change rate in the plurality of battery packs41in each charging period (hereinafter appropriately referred to as unit average temperature change rate). The statistical calculation unit113calculates an average value (hereinafter appropriately referred to as overall average temperature change rate) and a standard deviation value of the unit average temperature change rate in the plurality of battery packs41in each charging period.

The statistical calculation unit113calculates a Z value of the unit average temperature change rate in each battery pack41based on the overall average temperature change rate, the unit average temperature change rate in each battery pack41, and the standard deviation value of a plurality of unit average temperature change rates (see expression (1) below). The Z value is a value obtained by standardizing the unit average temperature change rate by defining the average value of the unit average temperature change rate to be 0 and the standard deviation value to be 1.

Z=(overall average temperature change rate−unit average temperature change rate)/standard deviation value   (expression 1).

It should be noted that a statistical value other than Z value may be used as long as it is a statistical value that can quantitatively evaluate a deviation of the unit average temperature change rate in the diagnosed battery pack41from the overall average temperature change rate. When the models of a plurality of electric-powered vehicles3are the same and the environments of usage are similar, for example, the deviation between the overall average temperature change rate and the unit average temperature change rate may be used directly.

The determination unit114determines the temperature adjustment function of the electric-powered vehicle3for which the deviation of the statistical value of the temperature change rate is equal to or greater than a standard deviation threshold value to be abnormal. Abnormalities of the temperature adjustment function include failure of the temperature adjustment equipment itself and failure of the temperature measurement system (for example, failure of a thermistor). In this embodiment, the determination unit114compares the standard deviation threshold value with the |Z value| of the unit average temperature change rate in each battery pack41and determines the temperature adjustment function of the electric-powered vehicle3for which the |Z value| of the unit average temperature change rate is equal to or greater than the standard deviation threshold value to be abnormal.

The failure detection service provider obtains the upper limit of the Z value of the unit average temperature change rate in a state where the temperature adjustment function of the electric-powered vehicle3is operating normally, based on actual data or simulation data. The failure detection service provider determines the standard deviation threshold value by adding a predetermined margin to the upper limit of the Z value of the unit average temperature change rate thus determined. For example, the standard deviation threshold value is generally set in a range of 2.0-4.0. If it is desired to detect signs of failure of the temperature adjustment function, the standard deviation threshold value may be set to be low. A common standard deviation threshold value may be preset for the entire electric-powered vehicles3, or the standard deviation threshold value may be preset for each model of the electric-powered vehicle3.

The determination unit114may compare the Z value of the unit average temperature change rate in each battery pack41with positive and negative standard deviation threshold values to diagnose an abnormality of the temperature adjustment function in more detail. When the Z value is equal to or greater than the positive standard deviation value, for example, the determination unit114assumes supercooling by the cooler43or insufficient heating by the heater44. When the Z value is equal to or less than the negative standard deviation value, conversely, the determination unit114assumes insufficient cooling by the cooler43or overheating by the heater44.

Further, when the average temperature change rate in the diagnosed battery pack41in the charging period is equal to or less than the lower limit threshold value or equal to or greater than the upper limit threshold value of the temperature change rate preset for each model, the determination unit114determines the temperature adjustment function of the electric-powered vehicle3equipped with the battery pack41to be abnormal. For example, the lower limit threshold value of the temperature change rate is set to 0. In the case the temperature change rate during charging becomes negative (the temperature decreases), it can be estimated that an abnormality has occurred in the temperature adjustment function. For example, the upper limit threshold value of the temperature change rate is set in a range of 10-20 [° C./h].

The notification unit115notifies the operation management terminal apparatus2of a result of diagnosis of the temperature adjustment function of the designated electric-powered vehicle3via the network5. Regarding the electric-powered vehicle3for which the temperature adjustment function is determined to be abnormal by the determination unit114, the notification unit115adds a message recommending that the temperature adjustment function be inspected. The delivery company repairs or replaces the battery when an abnormality is confirmed as a result of the inspection of the temperature adjustment function diagnosed as being abnormal.

FIG.4is a flowchart showing the flow of a process of detecting an abnormality of the temperature adjustment function according to the embodiment. The data acquisition unit111acquires one-month's battery data for a plurality of battery packs41mounted on a plurality of electric-powered vehicles3from the data server6(S10). The charging period data extraction unit112extracts temperature data in a plurality of charging periods from the battery data for each electric-powered vehicle3(S11).

The statistical calculation unit113calculates a temperature change rate in each electric-powered vehicle3in each charging period (S12). The statistical calculation unit113calculates the average temperature change rate in each electric-powered vehicle3in the charging period (S13). The statistical calculation unit113calculates an average value and a standard deviation value of the average temperature change rate in the plurality of electric-powered vehicles3in the charging period (S14).

The determination unit114determines whether the average temperature change rate in each electric-powered vehicle3in the charging period falls within a threshold value range between the lower limit threshold value Th_l and the upper limit threshold value Th_h (S15). The determination unit114determines the temperature adjustment function of the electric-powered vehicle3for which the average temperature change rate in the charging period does not fall within the threshold value range to be abnormal (S19).

The statistical calculation unit113calculates the Z value of the average temperature change rate in the charging period in all of the plurality of electric-powered vehicles3or in the electric-powered vehicle3for which the average temperature change rate in the charging period falls within the threshold value range (S16). The determination unit114compares the standard deviation threshold value Th_z with the |Z value| of the average temperature change rate in each electric-powered vehicle3in the charging period for which the average temperature change rate in the charging period falls within the threshold value range (S17). The determination unit114determines the temperature adjustment function of the electric-powered vehicle3for which the |z value| of the average temperature change rate in the charging period is less than the standard deviation threshold value Th_z to be normal (S18), and determines the temperature adjustment function of the electric-powered vehicle3for which the |Z value| is equal to or greater than the standard deviation threshold value Th_z to be abnormal (S19).

As described above, it is possible, according to this embodiment to diagnose the temperature adjustment function of the battery pack41at low cost while suppressing the influence of environmental temperature. In this embodiment, the temperature data in the charging period during which the temperature adjustment function is in effect is used so that the temperature adjustment function can be diagnosed with high accuracy. By comparing the temperature change rate in a plurality of electric-powered vehicles3in the charging period, the influence of environmental temperature can be eliminated. By detecting anomalous temperature data from the temperature data for a plurality of electric-powered vehicles3, an abnormality of the temperature adjustment function can be determined. When comparing the data for the plurality of electric-powered vehicles3, the diagnostic accuracy can be improved by comparing the temperature data for a plurality of electric-powered vehicles3of the same model or of similar environmental conditions (for example, charged by the same charger4).

In this embodiment, there is no need for a sensor for separately measuring the environmental temperature, and a sensor for measuring the cell temperature in the battery pack41is sufficient, so that the cost can be suppressed. Further, by using the Z value of the average temperature change rate in the charging period, a determination can be made by using the same threshold value regardless of the model of the electric-powered vehicle3. Further, by adjusting the value preset as the threshold value, it is possible to detect in advance signs of the occurrence of an abnormality of the temperature adjustment function.

Given above is a description of the present disclosure based on the embodiment. The embodiment is intended to be illustrative only and it will be understood by those skilled in the art that various modifications to combinations of constituting elements and processes are possible and that such modifications are also within the scope of the present disclosure.

In the above embodiment, the data acquisition unit111acquires battery data for a plurality of electric-powered vehicles3of the same model from the data server6. When the number of samples is large, it is not necessary to limit the battery data to those of the electric-powered vehicles3of the same model. The data acquisition unit111may, for example, acquire battery data for a plurality of electric-powered vehicles3from the same vehicle manufacturer. Alternatively, battery data for a plurality of electric-powered vehicles3belonging to the same delivery company may be acquired.

In the above embodiment, a four-wheeled electric-powered vehicle is assumed as the electric-powered vehicle3. The electric-powered vehicle3may be an electric motorcycle (electric scooter), an electric bicycle, or an electric kick scooter. Further, electric-powered vehicles include not only full-spec electric-powered vehicles but also low-speed electric-powered vehicles such as golf carts and land cars. Further, the target equipment on which the battery pack41is mounted is not limited to the electric-powered vehicle3. The target equipment on which the battery pack41is mounted includes electric ships, railway vehicles, electric mobile objects such as multicopters (drones), stationary electricity storage systems, and consumer electronic equipment (PCs, tablets, smartphones, etc.).

The embodiment may be defined by the following items.

An abnormality detection system (1) including:a data acquisition unit (111) that acquires temperature data for a plurality of battery packs (41) mounted on different equipment (3) in a predetermined period;a statistical calculation unit (113) that calculates, for each battery pack (41), a statistical value based on a temperature change rate in a plurality of charging periods included in the predetermined period; anda determination unit (114) that determines a temperature adjustment function of the equipment (3) for which a deviation of the statistical value based on the temperature change rate is equal to or greater than a threshold value to be abnormal.

Accordingly, it is possible to diagnose the temperature adjustment function of the battery pack (41) at low cost while suppressing the influence of environmental temperature.

The abnormality detection system (1) according to Item 1,wherein the statistical calculation unit (113):calculates, for each battery pack (41), an average, a median, or a mode of the temperature change rate in the plurality of charging periods included in the predetermined period and calculates a statistical temperature change rate in the plurality of battery packs (41) in a charging period respectively,calculates an average value and a standard deviation value of the statistical temperature change rate in the plurality of battery packs (41) in a charging period,calculates a Z value of the statistical temperature change rate of each battery pack (41) based on the average value and the standard deviation value of a plurality of statistical temperature change rates, anddetermines whether the temperature adjustment function of each equipment (3) is abnormal by comparing the Z value with the threshold value.

Accordingly, a determination can be made with the same threshold value regardless of the model of the equipment (3), by using the Z value of the average temperature change rate in a charging period.

The abnormality detection system (1) according to Item 1 or 2,wherein the data acquisition unit (111) acquires temperature data and current data for the plurality of battery packs (41) in a predetermined period,wherein the abnormality detection system (1) further includes:a charging period data extraction unit (112) that extracts temperature data in a period, in the predetermined period, during which a duration that a charging current is flowing falls within a preset time range, as temperature data in a charging period.

Accordingly, it is possible to diagnose the temperature adjustment function with high accuracy by using the temperature data in the charging period during which the temperature adjustment function is in effect.

The abnormality detection system (1) according to any one of Items 1 through 3,wherein the equipment (3) is an electric-powered vehicle (3), andwherein the plurality of battery packs (41) are battery packs (41) mounted on a plurality of electric-powered vehicles (3) of the same model.

Accordingly, the accuracy of diagnosis of the temperature adjustment function mounted on the electric-powered vehicle (3) can be improved.

The abnormality detection system (1) according to Item 2,wherein the equipment (3) is an electric-powered vehicle (3),wherein the plurality of battery packs (41) are battery packs (41) mounted on a plurality of electric-powered vehicles (3) of the same model, andwherein, when a statistical temperature change rate in the battery pack (41) in a charging period is equal to or less than a lower limit threshold value or equal to or greater than an upper limit threshold value of a temperature change rate preset for each model, the determination unit (114) determines the temperature adjustment function of the equipment (3) equipped with the battery pack (41) to be abnormal.

Accordingly, the accuracy of diagnosis of the temperature adjustment function mounted on the electric-powered vehicle (3) can be further improved.

An abnormality detection method including:acquiring temperature data for a plurality of battery packs (41) mounted on different equipment (3) in a predetermined period;calculating, for each battery pack (41), a statistical value based on a temperature change rate in a plurality of charging periods included in the predetermined period; anddetermining a temperature adjustment function of the equipment (3) for which a deviation of the statistical value based on the temperature change rate is equal to or greater than a threshold value to be abnormal.

Accordingly, it is possible to diagnose the temperature adjustment function of the battery pack (41) at low cost while suppressing the influence of environmental temperature.

An abnormality detection program including computer-implemented modules including:a module that acquires temperature data for a plurality of battery packs (41) mounted on different equipment (3) in a predetermined period;a module that calculates, for each battery pack (41), a statistical value based on a temperature change rate in a plurality of charging periods included in the predetermined period; anda module that determines a temperature adjustment function of the equipment (3) for which a deviation of the statistical value based on the temperature change rate is equal to or greater than a threshold value to be abnormal.

Accordingly, it is possible to diagnose the temperature adjustment function of the battery pack (41) at low cost while suppressing the influence of environmental temperature.