JP7159581B2 - Vehicle power system - Google Patents

Description

The present disclosure relates to vehicle power systems.

In an electric vehicle using a motor as a power source, or a hybrid vehicle using a motor and an engine as power sources, electric power may be supplied simultaneously from a plurality of power storage devices to equipment installed in the vehicle (for example, patent Reference 1).

JP 2015-070627 A

At present, next-generation rapid chargers with an output voltage of, for example, 1000V have been proposed in order to shorten the time required to charge a power storage device mounted on a vehicle. On the other hand, quick chargers with an output voltage of 500V are in widespread use. On the other hand, a conventional vehicle equipped with a plurality of power storage devices has a problem that it cannot be charged at a speed corresponding to these chargers.

Therefore, the present disclosure has been made in view of these points, and an object thereof is to provide a vehicle electric power system capable of charging at a speed corresponding to each of a plurality of chargers.

A vehicle power system according to a first aspect of the present disclosure is connected to a first line corresponding to a voltage of a first voltage value, is capable of outputting a voltage equal to or lower than the first voltage value, and is mounted on a vehicle. Power is supplied through a first power storage device that supplies power to the device connected to the first line, and a second line corresponding to a second voltage value higher than the first voltage value. a converter for stepping down a voltage to the voltage of the first voltage value and outputting the voltage to the first line; a converter connected to the second line and capable of outputting a voltage higher than the first voltage value; a second power storage device that supplies power to the device via a device; a connection unit that accepts connection of a charger that charges the first power storage device or the second power storage device; the connection unit and the first line; a first switching circuit for switching whether or not to connect the connection portion and the second line; a second switching circuit for switching whether or not to connect the connection portion to the second line; is connected, the first charger and the first power storage device are electrically connected by controlling the first switching circuit and the second switching circuit, and When the first charger and the second power storage device are not electrically connected to each other, and a second charger that supplies a voltage higher than the first voltage value is connected to the connecting portion, the first By controlling the switching circuit and the second switching circuit, the second charger and the second power storage device are electrically connected, and the second charger and the first power storage device are electrically connected. and a control device for disabling connection.

The vehicle power system further includes a third switching circuit that switches whether or not to electrically connect the converter and the first line, and the first power storage device includes a first power storage unit that stores power. and a first internal switching unit for switching whether or not to electrically connect the first power storage unit to the first line, and the second power storage device includes a second power storage unit for storing electric power. and a second internal switching unit for switching whether or not to electrically connect the second power storage unit to the second line, wherein the control device supplies power from the second power storage device to the device. When supplying power, the third switching circuit is controlled to connect the converter and the first line, and the second intra-device switching unit is controlled to connect the second power storage unit and the first line. 2 lines may be connected, and the first internal switching unit may be controlled so as not to connect the first power storage unit and the first line.

The control device connects either one of the first power storage device and the second power storage device to the device based on a priority order for electrically connecting the first power storage device and the second power storage device to the device. It may be electrically connected.

The first power storage device includes a first power storage unit that stores electric power, and a first specifying unit that specifies a first power storage amount that is the power storage amount in the first power storage unit. 1 When the first power storage device can supply power to the device based on the first power storage amount specified by the specifying unit, the first power storage unit may be preferentially connected to the device. good.

Advantageous Effects of Invention According to the present disclosure, it is possible to charge at a speed corresponding to each of a plurality of chargers.

BRIEF DESCRIPTION OF THE DRAWINGS It is a figure for demonstrating the outline|summary of the vehicle electric power system which concerns on embodiment. It is a figure which shows the structure of the 1st electrical storage apparatus which concerns on embodiment. It is a figure which shows the structure of the 2nd electrical storage apparatus which concerns on embodiment. 7 is a flow chart showing the flow of processing when power is supplied to the control device according to the embodiment; 7 is a flow chart showing the flow of processing of the control device when a charger is connected to the connecting portion according to the embodiment;

[Overview of Vehicle Power System S]
FIG. 1 is a diagram for explaining an overview of a vehicle electric power system S according to an embodiment. A vehicle power system S according to the embodiment is mounted on a vehicle and used to supply power to equipment 50 mounted on the vehicle. Although not limited, the vehicle power system S according to the embodiment is suitably used for large electric vehicles such as buses and trucks. In the following description, it is assumed that the vehicle is an electric vehicle such as a bus or truck.

The vehicle power system S is connected to a first line corresponding to a voltage of a first voltage value, and is capable of outputting a voltage equal to or lower than the first voltage value, and a second power storage device 20 higher than the first voltage value. a second power storage device 40 connected to a second line corresponding to a voltage value and capable of outputting a voltage higher than the first voltage value; a DC-DC converter 33 for stepping down the voltage to the first line, a connection unit 60 for receiving connection of a charger, and a control device 70.

When a charger that supplies a voltage equal to or lower than the first voltage value is connected to connection unit 60 , control device 70 electrically connects the charger and first power storage device 20 and also connects the charger and the first power storage device 20 . 2 The power storage device 40 is not electrically connected. Further, when a charger that supplies a voltage higher than the first voltage value is connected to connection unit 60, control device 70 electrically connects the charger and second power storage device 40, The device and the first power storage device 20 are not electrically connected.

In this manner, when a charger is connected, the vehicle power system S charges the chargeable power storage device corresponding to the voltage value of the voltage output from the charger. can be charged at a speed corresponding to

[Configuration of Vehicle Power System S]
Next, a detailed configuration of the vehicle power system S will be described. As shown in FIG. 1 , the vehicle power system S includes a first junction box 10, a first power storage device 20, a second junction box 30, a second power storage device 40, a device 50, a connection portion 60, and a , and a controller 70 .

First junction box 10 functions as a wiring section that electrically connects first power storage device 20, DC-DC converter 33, device 50, and connection section 60 via a first line. In this embodiment, the first junction box 10 is, for example, a 500V junction box.

The first junction box 10 has relay circuits 11 , 12 , 13 , 14 , 15 and 16 .
One end of the relay circuit 11 is connected to the positive terminal of the connection portion 60 . The other end of the relay circuit 11 is connected to the positive terminal of the first power storage device 20 , one end of the relay circuit 13 and one end of the relay circuit 15 . Relay circuit 11 functions as a first switching circuit, and switches between electrical connection between connecting portion 60 and first power storage device 20 under the control of control device 70 .

One end of the relay circuit 12 is connected to the negative terminal of the connecting portion 60 . The other end of the relay circuit 12 is connected to the negative terminal of the first power storage device 20 , one end of the relay circuit 14 and one end of the relay circuit 16 . Relay circuit 12 functions as a first switching circuit, and switches between electrical connection between connecting portion 60 and first power storage device 20 under the control of control device 70 .

One end of the relay circuit 13 is connected to the positive terminal of the first power storage device 20 , one end of the relay circuit 11 , and one end of the relay circuit 15 . The other end of relay circuit 13 is connected to the positive terminal of device 50 . The relay circuit 13 switches whether or not to electrically connect the device 50 , the first power storage device 20 and the relay circuit 15 under the control of the control device 70 .

One end of the relay circuit 14 is connected to the negative terminal of the first power storage device 20 , one end of the relay circuit 12 , and one end of the relay circuit 16 . The other end of relay circuit 14 is connected to the negative terminal of device 50 . Relay circuit 14 switches whether or not to electrically connect device 50 , first power storage device 20 and relay circuit 16 under the control of control device 70 .

One end of the relay circuit 15 is connected to the positive terminal of the first power storage device 20 , one end of the relay circuit 11 , and one end of the relay circuit 13 . The other end of the relay circuit 15 is connected to the positive terminal of the DC-DC converter 33 . The relay circuit 15 functions as a third switching circuit, and switches whether or not to electrically connect the DC-DC converter 33 and the first line according to the control of the control device 70 .

One end of the relay circuit 16 is connected to the negative terminal of the first power storage device 20 , one end of the relay circuit 12 , and one end of the relay circuit 14 . The other end of the relay circuit 16 is connected to the negative terminal of the DC-DC converter 33 . The relay circuit 16 functions as a third switching circuit, and switches whether or not to electrically connect the DC-DC converter 33 and the first line according to the control of the control device 70 .

The first power storage device 20 is connected to the first line of the first junction box 10 corresponding to the voltage of the first voltage value. The first power storage device 20 stores electric power supplied from the charger connected to the connection unit 60, and supplies the stored electric power to the device 50. A rechargeable energy storage system (REESS: Rechargeable Electrical Energy Storage System). is. In the present embodiment, the first power storage device 20 is a power storage device for driving at 500 V, and is capable of outputting a voltage equal to or lower than the first voltage value. FIG. 2 is a diagram showing the configuration of first power storage device 20 according to the embodiment.

As shown in FIG. 2, the first power storage device 20 includes a first power storage unit 21, a first internal switching unit 22, a positive terminal 23, a negative terminal 24, a first communication unit 25, and a first specific A unit 26 and a first control unit 27 are provided.

The first power storage unit 21 is, for example, a lithium ion battery, and stores electric power.
The first device switching unit 22 is, for example, a relay circuit, and switches whether or not to electrically connect the first power storage unit 21 and the first line of the first junction box 10 .

Plus terminal 23 is connected to the plus electrode of first power storage unit 21 via first internal switching unit 22 . Also, the positive terminal 23 is connected to the relay circuits 11, 13 and 15 of the first junction box 10 via the first line.

Negative terminal 24 is connected to the negative electrode of first power storage unit 21 via first internal switching unit 22 . Also, the negative terminal 24 is connected to the relay circuits 12, 14 and 16 of the first junction box 10 via the first line.

The first communication section 25 communicates with the control device 70 under the control of the first control section 27 .
The first identification unit 26 has, for example, a voltmeter that measures the voltage of the first power storage unit 21 . First identifying unit 26 identifies a first stored power amount, which is the amount of stored power in first power storage unit 21 , based on the voltage of first power storage unit 21 .

The first control unit 27 is a processor such as a CPU (Central Processing Unit), for example, and controls the first internal switching unit 22 and the first specifying unit 26 . The first control unit 27 causes the first specifying unit 26 to specify the first power storage amount based on the signal received from the control device 70 via the first communication unit 25 . Further, the first control unit 27 controls the first internal switching unit 22 based on a signal received from the control device 70 via the first communication unit 25 to switch whether or not to connect with the first line of

Second junction box 30 functions as a wiring portion that electrically connects first junction box 10, second power storage device 40, and connection portion 60 via a second line. In this embodiment, the second junction box 30 is, for example, a junction box for 1000V.

The second junction box 30 has relay circuits 31 and 32 and a DC-DC converter 33 .
One end of the relay circuit 31 is connected to the positive terminal of the connection portion 60 . The other end of the relay circuit 31 is connected to the positive terminal of the second power storage device 40 and the positive terminal of the DC-DC converter 33 . The relay circuit 31 functions as a second switching circuit, and determines whether or not to electrically connect the connection unit 60 to the DC-DC converter 33 and the second power storage device 40 according to the control of the control device 70. switch.

One end of the relay circuit 32 is connected to the negative terminal of the connecting portion 60 . The other end of the relay circuit 32 is connected to the negative terminal of the second power storage device 40 and the negative terminal of the DC-DC converter 33 . The relay circuit 32 functions as a second switching circuit, and determines whether or not to electrically connect the connection unit 60 to the DC-DC converter 33 and the second power storage device 40 according to the control of the control device 70. switch.

The DC-DC converter 33 steps down the voltage supplied via the second line in the second junction box 30 to the voltage of the first voltage value under the control of the control device 70 . The DC-DC converter 33 outputs the stepped-down voltage to the first line of the first junction box 10 . Here, it is assumed that the DC-DC converter 33 does not have the function of boosting the voltage of the first voltage value.

The second power storage device 40 is connected to the second line of the second junction box 30 corresponding to the voltage of the second voltage value. The second power storage device 40 stores power supplied from the charger connected to the connection unit 60, and supplies the stored power to the device 50 via the DC-DC converter 33. Rechargeable energy storage. System. In the present embodiment, the second power storage device 40 is a power storage device for driving at 1000 V, and is capable of outputting a voltage equal to or lower than the second voltage value. FIG. 3 is a diagram showing the configuration of the second power storage device 40 according to the embodiment.

As shown in FIG. 3, the second power storage device 40 includes a second power storage unit 41, a second internal switching unit 42, a positive terminal 43, a negative terminal 44, a second communication unit 45, and a second specific A unit 46 and a second control unit 47 are provided.

The second power storage unit 41 is, for example, a lithium ion battery, and stores electric power.
The second intra-device switching unit 42 is, for example, a relay circuit, and switches whether or not to electrically connect the second power storage unit 41 and the second line of the second junction box 30 .

The plus terminal 43 is connected to the plus electrode of the second power storage unit 41 via the second internal switching unit 42 . Also, the plus terminal 43 is connected to the relay circuit 31 of the second junction box 30 and the plus terminal of the DC-DC converter 33 via the second line.

The negative terminal 44 is connected to the negative electrode of the second power storage unit 41 via the second internal switching unit 42 . Also, the negative terminal 44 is connected to the negative terminals of the relay circuit 32 and the DC-DC converter 33 of the second junction box 30 via the second line.

The second communication section 45 communicates with the control device 70 under the control of the second control section 47 .
The second specifying unit 46 specifies the second power storage amount, which is the power storage amount in the second power storage unit 41 .

The second control unit 47 controls the second internal switching unit 42 and the second specifying unit 46 . The second control unit 47 causes the second specifying unit 46 to specify the second storage amount based on the signal received from the control device 70 via the second communication unit 45 . Further, the second control unit 47 controls the second intra-device switching unit 42 based on a signal received from the control device 70 via the second communication unit 45 so that the second power storage unit 41 and the second junction box 30 switch whether or not to connect with the second line of

The device 50 includes a motor section 51 and a high voltage auxiliary device 52 .
The motor unit 51 includes, for example, a motor control unit (not shown) and a motor (not shown), and operates by electric power supplied from the first power storage device 20 or the second power storage device 40 . Further, the motor unit 51 generates regenerative electric power by means of the motor, for example, when the vehicle is braked. The motor unit 51 supplies the generated regenerated power to the first power storage device 20 or the high voltage auxiliary device 52 .

The high-voltage auxiliary device 52 is, for example, a DC-DC converter, an AC compressor, a heater, a normal charger, or the like. It operates with power supplied from the device 40 or power supplied from the motor section 51 .

Connection unit 60 accepts connection of a charger that charges first power storage device 20 or second power storage device 40 . The connection unit 60 can be charged with a normal charger 100 capable of charging at a first speed, a first quick charger 110 capable of charging at a second speed higher than the first speed, or a third speed higher than the second speed. connection with the second rapid charger 120 is possible.

The normal charger 100 is, for example, a charger with an output voltage of 100 V or 200 V, an output current of 13 A, and a maximum output of 3 kW. The first rapid charger 110 is, for example, a charger with an output voltage of 500 V, an output current of 400 A or 125 A, and a maximum output of 200 kW. The normal charger 100 and the first rapid charger 110 function as first chargers that supply a voltage equal to or lower than the first voltage value.

The second rapid charger 120 is, for example, a charger with an output voltage of 750 V or 1000 V, an output current of 400 A, and a maximum output of 300 kW. The second quick charger 120 functions as a second charger that supplies a voltage higher than the first voltage value.

The connection unit 60 communicates with the control device 70 . For example, when the normal charger 100, the first quick charger 110 or the second quick charger 120 is connected, the connection unit 60 acquires type information indicating the type of the charger from the connected charger, The type information is transmitted to the control device 70 . The types of chargers are, for example, normal charging, quick charging, and next-generation quick charging.

The control device 70 is, for example, an ECU (Electronic Control Unit). The control device 70 is provided with a plurality of ports. For example, each of the plurality of ports includes first power storage device 20, second power storage device 40, relay circuits 11, 12, 13, 14, 15, 16, 31, 32, DC-DC converter 33, and connection section 60. is connected with The control device 70 communicates with the first power storage device 20, the second power storage device 40, the relay circuits 11, 12, 13, 14, 15, 16, 31, 32, the DC-DC converter 33, and the connection unit 60. .

In FIG. 1, the control device 70 and the first junction box 10 are connected by a dashed line. It shows that it is connected. Further, in FIG. 1, the control device 70 and the second junction box 30 are connected by a dashed line. It shows that it is connected.

The control device 70 controls the relay circuits 11, 12, 13, 14, 15, 16, 31, 32 and the DC-DC converter 33 provided in the first junction box 10, so that the first power storage device 20 and the second power storage device 40 are controlled to be connected to the connection unit 60 or to the device 50 .

Further, the control device 70 controls the first internal switching unit 22 and the second internal switching unit 42 via the first control unit 27 of the first power storage device 20 and the second control unit 47 of the second power storage device 40. By controlling, either one of the first power storage unit 21 and the second power storage unit 41 is connected to the device 50 or the connection unit 60 .

Here, the control device 70 controls the first internal switching unit 22 and the second internal switching unit 22 based on the order of priority for electrically connecting the first power storage unit 21 and the second power storage unit 41 to the device 50 or the connection unit 60 . Either one of the first power storage unit 21 and the second power storage unit 41 is connected to the device 50 or the connection unit 60 by controlling the unit 42 .

For example, the control device 70 is provided with storage units such as RAM (Random Access Memory) and ROM (Read Only Memory). The storage unit stores power supply priority information indicating the priority of the power storage device when power is supplied to the device 50 . The supply time priority information is, for example, information that associates the port number to which the power storage device is connected with the priority of the power storage device.

For example, the supply time priority information includes information that associates the priority "1" with the port number connected to the first power storage device 20 for normal charging and quick charging, the priority "2", and the following: and information that associates the second power storage device 40 for generation rapid charging with the port number to be connected. The supply priority information can be appropriately set by a terminal or the like that communicates with the control device 70 .

The storage unit also stores charging priority information indicating the priority of the power storage device when charging the power storage device from the charger connected to the connection unit 60 . The charging priority information is, for example, information that associates the type of charger, the port number to which the power storage device is connected, and the priority of the power storage device.

For example, if the charger type indicates next-generation rapid charging, the charger type includes a priority of "1" and a port connected to the second power storage device 40 for next-generation rapid charging. , and the priority "2" and the port number connected to the first power storage device 20 for normal charging and quick charging are associated. Note that the charging priority information can be appropriately set by a terminal or the like that communicates with the control device 70 .

[Control during power supply]
When the charger is not connected to the connection unit 60 , the control device 70 supplies power to the device 50 from the first power storage device 20 or the second power storage device 40 . Based on the first storage amount specified by the first specifying unit 26 of the first power storage device 20, the control device 70 controls the first power storage unit when the first power storage device 20 can supply power to the device 50. 21 is preferentially connected to the device 50 , control is performed so that electric power is supplied from the first power storage device 20 to the device 50 .

FIG. 4 is a flowchart showing the flow of processing when power is supplied by the control device 70 according to the embodiment. First, the control device 70 identifies the first power storage device 20 as the power storage device to which power is to be supplied, based on the supply time priority information stored in the storage unit (S1). Specifically, the supply time priority information includes information that associates the priority "1" with the port number connected to the first power storage device 20 for normal charge and quick charge, and the priority "2". and the port number connected to the second power storage device 40 for next-generation rapid charging. Select 20.

Subsequently, the control device 70 causes the first specifying unit 26 of the first power storage device 20 to specify the first power storage amount. The control device 70 determines whether or not the specified first power storage amount is equal to or less than a predetermined value (S2). If the control device 70 determines that the first power storage amount is equal to or less than the predetermined value, the process proceeds to S5, and if it determines that the first power storage amount is greater than the predetermined value, the control device 70 moves the process to S3.

Subsequently, the control device 70 connects the first power storage device 20 and the device 50, and starts power supply from the first power storage unit 21 to the device 50 (S3). Specifically, the control device 70 electrically connects the device 50 and the first power storage device 20 by controlling the relay circuits 13 and 14, and by controlling the relay circuits 11 and 12, The connection unit 60 and the first power storage device 20 are controlled so as not to be connected. Further, the control device 70 controls the relay circuits 15 and 16 so that the DC-DC converter 33 and the device 50 are not connected. Then, the control device 70 controls the first internal switching unit 22 of the first power storage device 20 to connect the first power storage unit 21 and the device 50 , thereby starting to supply power to the device 50 . Here, when regenerative power is generated by the motor unit 51 of the device 50, the power is stored in the first power storage device 20 specified in S1.

Subsequently, the control device 70 causes the first specifying unit 26 of the first power storage device 20 to specify the first power storage amount. The control device 70 determines whether or not the specified first power storage amount is equal to or less than a predetermined value (S4). If the control device 70 determines that the first power storage amount is equal to or less than the predetermined value, the process proceeds to S5, and if it determines that the first power storage amount is greater than the predetermined value, it re-executes S4.

Subsequently, the control device 70 identifies the second power storage device 40 as the power storage device to which power is to be supplied, based on the supply time priority information stored in the storage unit (S5).
Subsequently, the control device 70 causes the second specifying unit 46 of the second power storage device 40 to specify the second power storage amount. The control device 70 determines whether or not the specified second power storage amount is equal to or less than a predetermined value (S6). When the control device 70 determines that the second power storage amount is equal to or less than the predetermined value, the control device 70 shifts the processing to S<b>9 and stops power supply to the device 50 . When the control device 70 determines that the second power storage amount is larger than the predetermined value, the control device 70 shifts the process to S7.

Subsequently, the control device 70 connects the second power storage device 40 and the device 50 to start power supply from the second power storage unit 41 to the device 50 (S7). Specifically, the controller 70 connects the DC-DC converter 33 and the first line by controlling the relay circuits 15 and 16 . Further, the control device 70 electrically connects the device 50 with the first power storage device 20 and the DC-DC converter 33 by controlling the relay circuits 13 and 14 . In addition, control device 70 controls relay circuits 11 , 12 , 31 and 32 so as not to connect connecting portion 60 to second power storage device 40 and DC-DC converter 33 .

Then, the control device 70 controls the second internal switching unit 42 of the second power storage device 40 to connect the second power storage unit 41 and the second line, whereby the second power storage unit 41 and DC-DC conversion are connected. It electrically connects with the device 33 . Control device 70 also controls DC-DC converter 33 to step down the voltage output from second power storage unit 41 and supply the stepped-down voltage to device 50 .

Here, since the first power storage device 20 is also connected to the device 50, the control device 70 controls the first internal switching unit 22 of the first power storage device 20 to switch between the first power storage unit 21 and the first line. control so that they are not connected to each other. Thereby, the control device 70 prevents power from being supplied from the first power storage unit 21 to the device 50 .

Subsequently, the control device 70 causes the second specifying unit 46 of the second power storage device 40 to specify the second power storage amount. The control device 70 determines whether or not the specified second power storage amount is equal to or less than a predetermined value (S8). When the control device 70 determines that the second power storage amount is equal to or less than the predetermined value, the control device 70 shifts the processing to S<b>9 and stops power supply to the device 50 . Further, when the control device 70 determines that the second power storage amount is larger than the predetermined value, the control device 70 re-executes S8. Here, when regenerative electric power is generated by the motor unit 51 of the device 50 , the electric power is supplied to the high voltage auxiliary device 52 .

[Control during charging]
Control device 70 charges first power storage device 20 or second power storage device 40 when normal charger 100 , first quick charger 110 or second quick charger 120 is connected to connection unit 60 . When the first charger (ordinary charger 100 or first quick charger 110) that supplies a voltage equal to or lower than the first voltage value is connected to the connection unit 60, the controller 70 controls the relay circuits 11, 12, 31 and 32, the first charger and the first power storage device 20 are electrically connected, and the first charger and the second power storage device 40 are not electrically connected. Further, when a second charger (second quick charger 120) that supplies a voltage higher than the first voltage value is connected to the connection unit 60, the control device 70 activates the relay circuits 11, 12, 31 and 32. By controlling, the second charger and the second power storage device 40 are electrically connected, and the second charger and the first power storage device 20 are not electrically connected.

FIG. 5 is a flowchart showing the flow of processing of control device 70 when a charger is connected to connection unit 60 according to the embodiment.
First, the control device 70 identifies the type of the charger connected to the connection unit 60 by acquiring type information indicating the type of the charger connected from the connection unit 60 (S11).
Subsequently, the control device 70 identifies the type of the charger connected to the connection unit 60 by acquiring type information indicating the type of the connected charger from the connection unit 60 (S12).

Subsequently, the control device 70 selects a power storage device to be charged based on the identified charger type, the first and second power storage amounts, and the charging priority information stored in the storage unit. Specify (S13). Specifically, first, the control device 70 refers to the charging priority information stored in the storage unit, and specifies the port number with the highest priority for the specified charger type. Choose a high power storage device.

For example, when the specified charger type is for normal charging or for quick charging, control device 70 selects first power storage device 20 as the power storage device with the highest priority. Further, when the identified charger type is for next-generation rapid charging, control device 70 selects second power storage device 40 as the power storage device with the highest priority.

Subsequently, the control device 70 determines whether or not the amount of electricity stored in the selected power storage device exceeds a predetermined threshold indicating that the amount of electricity can be charged. Control device 70 identifies the specified power storage device as the power storage device to be charged when the amount of power stored in the specified power storage device does not exceed a predetermined threshold value and the power storage device is chargeable.

Further, when the selected power storage device cannot be charged, the control device 70 refers to the charging priority information stored in the storage unit, and specifies a port number with a low priority for the specified charger type. selects a power storage device with a lower priority. Then, the control device 70 determines whether or not the power storage amount of the power storage device with the lower priority exceeds a predetermined threshold. Control device 70 identifies the power storage device with low priority as the power storage device to be charged when the amount of power stored in the power storage device with low priority does not exceed a predetermined threshold value and the power storage device is chargeable.

Subsequently, the control device 70 determines whether or not the power storage device to be charged has been specified as a result of the processing in S13 (S14). If the control device 70 determines that the power storage device to be charged has been identified, the process proceeds to S15, and if it is determined that the power storage device to be charged has not been identified, the processing related to this flowchart ends.

Subsequently, the control device 70 connects the specified power storage device and the connection unit 60 to start charging (S15). For example, when the normal charger 100 or the first quick charger 110 is connected to the connection unit 60 and the first power storage device 20 is specified as the power storage device to be charged, the control device 70 controls the relay circuit 11, 12, 31, and 32 are controlled to electrically connect the connection portion 60 and the first power storage device 20, and the connection portion 60 and the second power storage device 40 are not electrically connected. Then, the control device 70 controls the relay circuits 13 , 14 , 15 and 16 so that the first power storage device 20 is disconnected from the DC-DC converter 33 and the device 50 . Then, control device 70 electrically connects normal charger 100 or first quick charger 110 to first power storage unit 21 by controlling first device switching unit 22 . Further, the control device 70 controls the second internal switching unit 42 so as not to electrically connect the second power storage unit 41 and the second line.

Further, when second quick charger 120 is connected to connection unit 60 and second power storage device 40 is specified as the power storage device to be charged, control device 70 controls relay circuits 11 , 12 , 31 and 32 . is controlled to electrically connect the connection unit 60 and the second power storage device 40, and the connection unit 60 and the first power storage device 20 are not electrically connected. The controller 70 controls the relay circuits 15 and 16 so that the DC-DC converter 33 is not connected to the device 50 . Then, control device 70 electrically connects second quick charger 120 and second power storage unit 41 by controlling second internal switching unit 42 . Here, the control device 70 controls the first intra-device switching unit 22 so that power is not supplied from the first power storage device 20 to the device 50 .

Note that the control device 70 may control the first intra-device switching unit 22 so that electric power is supplied from the first power storage device 20 to the device 50 . By doing so, power can be stably supplied from the first power storage device 20 to the device 50 even when the second power storage device 40 is being charged.

Subsequently, the control device 70 causes the specifying unit of the power storage device to be charged to specify the amount of power stored in the power storage unit of the power storage device at predetermined time intervals. Then, control device 70 determines whether or not the power storage device to be charged is fully charged (S16). When the control device 70 determines that the power storage device to be charged is fully charged, the control device 70 shifts the process to S17 and causes the charger to finish charging. If the power storage device to be charged is not fully charged, control device 70 re-executes S16. Although the control device 70 causes the specifying unit of the power storage device to be charged to specify the amount of power stored in the power storage unit of the power storage device at predetermined time intervals, the present invention is not limited to this. In response to the power storage unit of the power storage device being fully charged, the control unit of the power storage device may notify the control device 70 of the full charge.

When second quick charger 120 is connected and second power storage device 40 is specified as the power storage device to be charged, control device 70 controls each relay circuit when second power storage device 40 is fully charged. Also, the second quick charger 120 and the first power storage device 20 may be electrically connected via the DC-DC converter 33 by controlling the internal switching unit of each power storage device. Then, the control device 70 may supply the voltage stepped down by the DC-DC converter 33 to the first power storage device 20 to charge the first power storage device 20 .

<Effects of Embodiment>
As described above, in the vehicle power system S according to the embodiment, when the normal charger 100 or the first quick charger 110 that supplies a voltage equal to or lower than the first voltage value is connected to the connection unit 60, the The charger and first power storage device 20 are electrically connected, and the charger and second power storage device 40 are not electrically connected. Further, when second quick charger 120 that supplies a voltage higher than the first voltage value is connected to connection unit 60 , control device 70 electrically connects the charger and second power storage device 40 . At the same time, the charger and first power storage device 20 are not electrically connected. By doing so, the vehicle power system S can perform charging at a speed corresponding to each of the plurality of chargers.

Further, when first power storage device 20 is capable of supplying power to device 50 , vehicle power system S preferentially connects first power storage unit 21 to device 50 so that first power storage device 20 power is supplied to the device 50 from the The DC-DC converter 33 does not have a step-up function and cannot supply the regenerated electric power generated by the motor unit 51 to the second power storage device 40, whereas the first power storage device 20 has The regenerated power can be supplied as it is. Therefore, the vehicle power system S can preferentially use the first power storage device 20 and increase the state in which the first power storage device 20 can be charged. 20 can be charged.

Although the present invention has been described above using the embodiments, the technical scope of the present invention is not limited to the scope described in the above embodiments. It is obvious to those skilled in the art that various modifications or improvements can be made to the above embodiments. It is clear from the description of the scope of claims that forms with such modifications or improvements can also be included in the technical scope of the present invention.

Reference Signs List 10 First junction boxes 11, 12, 13, 14, 15, 16 Relay circuit 20 First power storage device 21 First power storage unit 22 First device switching unit 23... plus terminal 24... minus terminal 25... first communication section 26... first identification section 27... first control section 30... second junction boxes 31, 32... Relay circuit 33 DC-DC converter 40 Second power storage device 41 Second power storage unit 42 In-device switching unit 43 Plus terminal 44 Negative terminal 45 Second communication unit 46 Second identification unit 47 Second control unit 50 Device 51 Motor unit 52 High voltage auxiliary device 60 Connection unit 70 Control device 100 Normal charger 110 First quick charger 120 Second quick charger S Vehicle electric power system

Claims (3)

A device mounted on a vehicle, which is connected to a first line corresponding to a voltage of a first voltage value, is capable of outputting a voltage equal to or lower than the first voltage value, and is connected to the first line. a first power storage device that supplies power to a first power storage unit that stores power; and a first internal switching unit that switches whether or not to electrically connect the first power storage unit to the first line. and a first power storage device having
a converter for stepping down a voltage supplied through a second line corresponding to a second voltage value higher than the first voltage value to a voltage of the first voltage value and outputting the voltage to the first line;
A second power storage device connected to the second line, capable of outputting a voltage higher than the first voltage value, and supplying power to the device via the converter, the second power storage device storing power. a second power storage device having two power storage units and a second intra-device switching unit that switches whether to electrically connect the second power storage unit to the second line ;
a connection unit that accepts connection of a charger that charges the first power storage device or the second power storage device;
a first switching circuit that switches whether or not to connect the connecting portion and the first line;
a second switching circuit that switches whether or not to connect the connecting portion and the second line;
a third switching circuit for switching whether or not to electrically connect the converter and the first line;
When a first charger that supplies a voltage equal to or lower than the first voltage value is connected to the connecting portion, the first charger and the second charger are controlled by controlling the first switching circuit and the second switching circuit. 1 power storage device is electrically connected, the first charger and the second power storage device are not electrically connected, and a voltage higher than the first voltage value is supplied to the connecting portion. When the two chargers are connected, by controlling the first switching circuit and the second switching circuit, the second charger and the second power storage device are electrically connected, and the second charging is performed. When the device and the first power storage device are not electrically connected and power is supplied from the second power storage device to the device, the converter and the first power storage device are controlled by controlling the third switching circuit. By connecting the first line and controlling the second in-device switching unit, connecting the second power storage unit and the second line, and controlling the first in-device switching unit, the a control device that controls so as not to connect the first power storage unit and the first line ;
A vehicle power system comprising: The control device connects either one of the first power storage device and the second power storage device to the device based on a priority order for electrically connecting the first power storage device and the second power storage device to the device. make an electrical connection
The vehicle electric power system according to claim 1 . A device mounted on a vehicle, which is connected to a first line corresponding to a voltage of a first voltage value, is capable of outputting a voltage equal to or lower than the first voltage value, and is connected to the first line. a first power storage device that supplies electric power to a first power storage device, the first power storage device having a first power storage unit that stores power and a first specifying unit that specifies a first power storage amount that is the power storage amount in the first power storage unit a device;
a converter for stepping down a voltage supplied through a second line corresponding to a second voltage value higher than the first voltage value to a voltage of the first voltage value and outputting the voltage to the first line;
A second power storage device connected to the second line, capable of outputting a voltage higher than the first voltage value, and supplying power to the device via the converter, the second power storage device storing power. a second power storage device having two power storage units;
a connection unit that accepts connection of a charger that charges the first power storage device or the second power storage device;
a first switching circuit that switches whether or not to connect the connecting portion and the first line;
a second switching circuit that switches whether or not to connect the connecting portion and the second line;
When a first charger that supplies a voltage equal to or lower than the first voltage value is connected to the connecting portion, the first charger and the second charger are controlled by controlling the first switching circuit and the second switching circuit. 1 power storage device is electrically connected, the first charger and the second power storage device are not electrically connected, and a voltage higher than the first voltage value is supplied to the connecting portion. When the two chargers are connected, by controlling the first switching circuit and the second switching circuit, the second charger and the second power storage device are electrically connected, and the second charging is performed. the first power storage device and the first power storage device are not electrically connected to each other, and the first power storage device and the second power storage device are determined based on the order of priority for electrically connecting the first power storage device and the second power storage device to the device. Either one of the second power storage devices is electrically connected to the device, and the first power storage device is capable of supplying power to the device based on the first storage amount specified by the first specifying unit. a control device that preferentially connects the first power storage device to the device when the determination is made;
A vehicle power system comprising:

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