JP7307007B2 - electric car - Google Patents

Description

TECHNICAL FIELD The technology disclosed in this specification relates to an electric vehicle, and more particularly to an electric vehicle that is charged by a charging facility.

Patent Literature 1 discloses an electric vehicle that is charged by a charging facility. This electric vehicle includes a charging inlet to which a charging connector of a charging facility is detachably connected.

JP 2019-187035 A

Generally, in the electric vehicle as described above, a temperature sensor is provided in the charging inlet, and the charging current is controlled according to the temperature measured by the temperature sensor. This reduces the charging time while avoiding overheating of the contact points between the charging inlet and the charging connector. However, placing the temperature sensor at the actual contact point between the charging inlet and the charging connector is difficult because it interferes with the mating of the charging inlet and the charging connector. Therefore, the temperature measured by the temperature sensor does not necessarily match the actual temperature at the contact point between the charging inlet and the charging connector, and there is an error between the two. In particular, some charging equipment has a cooling system for the charging connector, and the temperature gradient (temperature distribution) that appears between the charging inlet and the charging connector varies depending on the presence or absence of the cooling system. Therefore, different errors occur between the temperature measured by the temperature sensor and the actual temperature at the contact depending on the presence or absence of the cooling system.

In view of the above circumstances, the present specification provides a technique for more accurately ascertaining the temperature of the contact point between the charging inlet and the charging connector.

An electric vehicle disclosed in this specification includes a charging inlet to which a charging connector of a charging facility is detachably connected, a first temperature sensor that measures the temperature of the charging inlet, and temperature-related data related to the temperature of the charging connector. and a processing circuit for estimating the temperature at the junction between the charging connector and the charging inlet based on the temperature measured by the first temperature sensor and the temperature-related data. The temperature-related data includes at least one of presence/absence of a cooling system for the charging connector of the charging facility and temperature measured by a second temperature sensor provided at the charging connector of the charging facility.

According to the above configuration, in addition to the temperature measured by the first temperature sensor of the charging inlet, the temperature at the contact point between the charging inlet and the charging connector is obtained by using temperature-related data related to the temperature of the charging connector, can be estimated more accurately. In particular, the temperature-related data includes at least one of the presence or absence of a cooling system for the charging connector of the charging facility and the temperature measured by the second temperature sensor provided on the charging connector of the charging facility. For example, if the presence or absence of a cooling system for the charging connector is known, the relational expression for estimating the temperature at the contacts using the temperature measured by the first temperature sensor can be changed according to the presence or absence of the cooling system. Alternatively, if the temperature measured by the second temperature sensor provided on the charging connector is known, the temperature of the contact located between the two temperature sensors can be estimated more accurately. As a result, even in various charging facilities, the charging current can be controlled more appropriately, and for example, the charging time can be shortened.

The structure of the electric vehicle 10 and the charging equipment 40 which charges it is shown typically. A charging inlet 20 and a charging connector 30 connected thereto are schematically shown. FIG. 2 is a diagram schematically showing a charging inlet 20 and a charging connector 30 connected thereto, showing an example in which the charging connector 30 is provided with a second temperature sensor 32. FIG.

An electric vehicle 10 of an embodiment will be described with reference to the drawings. The electric vehicle 10 includes a charging inlet 20 as shown in FIGS. 1 and 2 . Charging inlet 20 is provided in a portion of electric vehicle 10, but its position is not particularly limited. The electric vehicle 10 referred to here is not particularly limited, but is, for example, an electric vehicle or a plug-in hybrid vehicle, and is equipped with a charging mechanism that receives power from an external power source such as a charging facility 40 through a charging cable 42 and stores the power in an on-vehicle power storage device 28. It is

Charging inlet 20 is a connector on the power receiving side, and is detachably connected to charging connector 30 of charging facility 40 . Therefore, the charging inlet 20 receives power supplied from the external power supply via the charging connector 30 and stores the power in the power storage device 28 mounted on the electric vehicle 10 .

The electric vehicle 10 further includes a first temperature sensor 22 . The first temperature sensor 22 is located near the charging inlet 20 or built in the charging inlet 20 and detects the temperature of the charging inlet 20 . Here, the specific configuration of the first temperature sensor 22 is not particularly limited. The first temperature sensor 22 may be any sensor that can directly or indirectly measure the temperature of the charging inlet 20 .

The electric vehicle 10 further includes a communication device 24 . The communication device 24 communicates various data with the charging facility 40 and the outside by wire or wirelessly. Communication device 24 obtains temperature-related data, for example, related to the temperature of charging connector 30 . Temperature-related data includes the presence or absence of cooling system 34 for charging connector 30 of charging facility 40 . A specific method of acquiring the temperature-related data in the communication device 24 is not particularly limited. The communication device 24 may be any device that can directly or indirectly acquire temperature-related data. For example, the electric vehicle 10 may further include a memory that stores information about temperature-related data, and the communication device 24 may indirectly acquire the temperature-related data by referring to the memory. Specifically, the memory of the electric vehicle 10 may store identification information and a database describing the presence or absence of the cooling system 34 for a plurality of charging facilities 40 . In this case, it is sufficient for the communication device 24 of the electric vehicle 10 to acquire only the identification information from the charging equipment 40 as the temperature-related data. Alternatively, the temperature-related data may be acquired indirectly through communication between a server provided outside the electric vehicle 10 and the communication device 24 . The acquisition of the temperature-related data by the communication device 24 may be performed before or after the electric vehicle 10 and the charging facility 40 are connected.

Electric vehicle 10 further comprises processing circuitry 26 . The processing circuit 26 is connected to the first temperature sensor 22 and acquires the temperature measured by the first temperature sensor 22 , ie the temperature of the charging inlet 20 . The processing circuit 26 is further connected to the communication device 24 and acquires the temperature-related data acquired by the charging connector 30 from the communication device 24 . That is, the temperature of the charging inlet 20 measured by the first temperature sensor 22 and the temperature-related data of the charging connector 30 acquired by the communication device 24 are input to the processing circuit 26 . Therefore, processing circuit 26 determines the temperature of charging connector 30 and charging inlet 20 based on the temperature of charging inlet 20 measured by first temperature sensor 22 and the temperature-related data of charging connector 30 acquired by communication device 24 . Estimate the temperature at the junction between If the estimated temperature at the contact between charging connector 30 and charging inlet 20 exceeds a predetermined value, processing circuitry 26 may control, for example, limiting charging power to avoid overheating. The predetermined value may be designed in consideration of the heat resistance temperature of the cable of charging inlet 20, the charging time, and the like.

Hereinafter, the contact between charging connector 30 and charging inlet 20 may be abbreviated as contact, and the temperature at the contact may be abbreviated as contact temperature.

According to the above configuration, even when charging facility 40 has cooling system 34 for charging connector 30 for suppressing overheating of the contacts, electric powered vehicle 10 can more accurately estimate the contact temperature. Electric powered vehicle 10 can more accurately estimate the contact temperature by using temperature-related data regarding the temperature of charging connector 30 in addition to measurement by first temperature sensor 22 of charging inlet 20 . The temperature-related data includes the presence or absence of the cooling system 34 for the charging connector 30 of the charging facility 40, as described above.

For example, the case where charging facility 40 includes cooling system 34 for charging connector 30 will be described below. The temperature gradient (temperature distribution) that appears between charging inlet 20 and charging connector 30 differs depending on the presence or absence of cooling system 34 for charging connector 30 . Specifically, charging connector 30 with cooling system 34 maintains a lower temperature due to cooling by cooling system 34 as compared to charging connector 30 without cooling system 34 . That is, the temperature of charging connector 30 changes depending on the presence or absence of cooling system 34 . Therefore, as described above, the temperature gradient (temperature distribution) that appears between charging inlet 20 and charging connector 30 also differs depending on the presence or absence of cooling system 34 for charging connector 30 . When the temperature-related data acquired by the communication device 24 indicates the presence or absence of the cooling system 34 , the processing circuit 26 changes the relational expression for estimating the contact temperature according to the presence or absence of the cooling system 34 . As a result, the contact temperature can be grasped more accurately.

On the other hand, the charging facility 40 may comprise a second temperature sensor 32, as shown in FIG. The second temperature sensor 32 , for example, is located near the charging connector 30 or built in the charging connector 30 and detects the temperature of the charging connector 30 . Here, the specific configuration of the second temperature sensor 32 is not particularly limited. The second temperature sensor 32 may be any sensor that can directly or indirectly measure the temperature of the charging connector 30 .

A case where the charging facility 40 includes the second temperature sensor 32 will be described below. If the charging facility 40 includes the second temperature sensor 32, the communication device 24 may acquire the temperature measured by the second temperature sensor 32 provided in the charging connector 30 as the temperature-related data. At this time, the temperature-related data may or may not include information about the presence or absence of cooling system 34 for charging connector 30 . When the temperature measured by the second temperature sensor 32 is determined from the temperature-related data, the processing circuit 26 detects the temperature measured by the first temperature sensor 22 provided in the charging inlet 20 and the temperature measured by the second temperature sensor 32 to determine the contact point. Temperature can be estimated more accurately. Specifically, using the temperature gradient that appears between the temperatures measured by the two temperature sensors 22, 32 and the relationship that estimates the junction temperature using each measurement, the processing circuit 26 can more accurately determine the junction temperature. can be estimated to

Either one of the estimation of the contact temperature by the relational expression that considers the presence or absence of the cooling system 34 and the estimation of the contact temperature that considers the temperature measured by the second temperature sensor 32 may be executed, and both are executed in parallel. may be Therefore, the temperature-related data acquired by the communication device 24 may include at least one of the presence or absence of the cooling system 34 of the charging connector 30 and the temperature measured by the second temperature sensor 32 provided on the charging connector 30 . With the configuration described above, the electric vehicle 10 can more appropriately control the charging current even in various charging facilities 40 . As a result, for example, the charging time from the charging equipment 40 can be shortened.

Although several specific examples have been described in detail above, these are merely examples and do not limit the scope of the claims. The technology described in the claims includes various modifications and changes of the specific examples illustrated above. The technical elements described in this specification or drawings exhibit technical usefulness either singly or in combination.

10: Electric vehicle 20: Charging inlet 22: First temperature sensor 24: Communication device 26: Processing circuit 28: Power storage device 30: Charging connector 32: Second temperature sensor 34: Cooling system 40: Charging facility 42: Charging cable

Claims (1)

a charging inlet to which a charging connector of the charging facility is detachably connected;
a first temperature sensor that measures the temperature of the charging inlet;
a communication device that acquires temperature-related data related to the temperature of the charging connector;
a processing circuit for estimating a temperature at a junction between the charging connector and the charging inlet based on the temperature measured by the first temperature sensor and the temperature-related data;
with
The temperature-related data includes at least one of presence/absence of a cooling system for the charging connector of the charging facility and a temperature measured by a second temperature sensor provided at the charging connector of the charging facility.
electric car.

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