JP7494871B2 - Charge control device and charge control method - Google Patents

Description

This disclosure relates to a charging control device and a charging control method.

A power control device that performs continuous charging control to continuously charge a battery is known (see, for example, Patent Document 1).

There is also a known charging control device that temporarily stops continuous charging when the remaining battery charge (State Of Charge: SOC) reaches a threshold value or a value close to the threshold value (see, for example, Patent Document 2).

JP 2013-131449 A JP 2012-244663 A

However, when an instruction value is sent to a charger based on the charging power that is permissible for the battery pack, and a battery pack connected to the charger is charged with the charging power sent to the charger, the first charging power value that is permissible for the battery pack and the second charging power value, which is the numerical value of the charging power with which the battery pack is actually charged, may differ from each other.

If the first charging power value is lower than the second charging power value, the charging time until the battery pack is fully charged will be longer, and charging will not be efficient. Also, if the first charging power value is higher than the second charging power value, overcharging may occur, and safety may not be guaranteed.

The objective of this disclosure is to provide a charging system and a charging control method for the charging system that can efficiently charge a battery pack while ensuring safety.

In order to achieve the above object, the charging control device according to the present disclosure includes:
A charge control device in a power supply system having a battery pack connected to a charger,
an estimation unit that estimates a charging power value permitted by the battery pack;
a first calculation unit that calculates a first charging power value that is permissible for the battery pack based on the estimated charging power value;
a control unit that instructs the charger of an instruction value based on the calculated first charging power value;
a second calculation unit that calculates a difference between a second charging power value, which is a numerical value of charging power with which the battery pack is actually charged, and the first charging power value, when the charger charges the battery pack based on the instruction value;
Equipped with
The control unit sets the first charging power value as the instruction value when the first charging power value is greater than the second charging power value due to the difference, and sets the first charging power value as the instruction value when the second charging power value is greater than the first charging power value .

The charging control device according to the present disclosure includes:
A charge control device in a power supply system having a battery pack composed of a plurality of battery packs connected in parallel to a charger,
an estimation unit that estimates a charging power value permitted for each of the plurality of battery packs;
a first calculation unit that calculates a first charging power value that is permissible for the battery pack based on the estimated charging power value;
a control unit that instructs the charger of an instruction value based on the calculated first charging power value;
a second calculation unit that calculates a difference between a second charging power value, which is a numerical value of charging power with which the battery pack is actually charged, and the first charging power value, when the charger charges the battery pack based on the instruction value;
Equipped with
The control unit sets the first charging power value as the instruction value when the first charging power value is greater than the second charging power value due to the difference, and sets the first charging power value as the instruction value when the second charging power value is greater than the first charging power value .

The charging control method according to the present disclosure includes:
A charging control method in a power supply system having a battery pack composed of a plurality of battery packs connected in parallel to a charger, comprising:
estimating a charging power value permitted by each of the plurality of battery packs;
calculating a first charging power value that is permissible for the battery pack based on the estimated charging power value;
instructing the charger to set an instruction value based on the calculated first charging power value;
calculating a difference between a second charging power value, which is a numerical value of charging power with which the battery pack is actually charged, and the first charging power value, when the charger charges the battery pack based on the instruction value;
setting the first charging power value as the instruction value when the first charging power value is greater than the second charging power value according to the calculated difference, and setting the first charging power value as the instruction value when the second charging power value is greater than the first charging power value ;
Equipped with.

This disclosure makes it possible to efficiently charge a battery pack while ensuring safety.

FIG. 1 is a diagram showing a configuration of a charging control device according to an embodiment of the present disclosure. FIG. 2 is a diagram showing an example of charging power permitted for a battery pack. FIG. 3 is a diagram showing an example of the minimum value and the actual charging power. FIG. 4 is a flowchart illustrating an example of a charge control method according to an embodiment of the present disclosure.

Hereinafter, embodiments of the present disclosure will be described with reference to the drawings.
Fig. 1 is a diagram showing a configuration of a charge control device 10 according to an embodiment of the present disclosure. As shown in Fig. 1, a plurality of battery packs BP constituting a battery pack BU are shown. The battery pack BU is mounted on, for example, a vehicle.

The charger 1 is installed on the ground. A number of battery packs BP are connected in parallel to the charger 1. The number of battery packs BP connected in parallel to the charger 1 is n (n is an integer equal to or greater than 2). The charger 1 has a charger ECU (Electronic Control Unit) 2. The charger ECU 2 controls the charger 1 so that a predetermined charging power is sent to the electrical path 3. The multiple battery packs BP are charged with the charging power sent to the electrical path 3. Each of the multiple battery packs BP is connected to a branch path 3a of the electrical path 3.

The charging control device 10 includes a monitoring unit 20, a battery ECU 30, and a control ECU 40 (corresponding to the "control unit" in this disclosure).

[Monitoring unit 20]
The monitoring unit 20 is provided for each battery pack BP and has a function of estimating a charging power value permitted by the battery pack BP according to the state of the battery pack BP (temperature, charging state, deterioration state, etc.) (corresponding to the "estimation unit" in the present disclosure). The estimated charging power value is transmitted to the battery ECU 30. The monitoring unit 20 also has a function of detecting the charging power with which the battery pack BP is actually charged. The detected value is transmitted to the battery ECU 30.

[Battery ECU 30]
The battery ECU 30 includes a central processing unit (CPU), a read only memory (ROM), a random access memory (RAM), etc. The CPU reads out a program corresponding to the processing contents from the ROM, loads it into the RAM, and executes a predetermined function of the battery ECU 30 in cooperation with the loaded program. At this time, various data stored in a memory unit (not shown) is referenced. The memory unit is configured, for example, of a non-volatile semiconductor memory (so-called flash memory) or a hard disk drive. The battery ECU 30 may be incorporated, for example, in a vehicle electronic control unit (ECU) that controls each part of the vehicle, may be configured integrally with the control ECU 40, or may be provided separately from the vehicle ECU and the control ECU 40.

The battery ECU 30 has a function (corresponding to the "first calculation unit" in this disclosure) of calculating a first charging power value that is permitted for the battery pack BU based on the estimated charging power value transmitted from the monitoring unit 20. The first charging power value is transmitted to the control ECU 40.

A more detailed explanation will be given with reference to FIG. 2. FIG. 2 is a diagram showing an example of a charging power value that is permitted for a battery pack BP. As shown in FIG. 2, the charging power value permitted for battery pack BP1 is "10 kW". The charging power value permitted for battery pack BP2 is "5 kW". The charging power value permitted for battery pack BPn is "8 kW".

The battery ECU 30 selects the minimum value from among the charge power values that can be permitted for each of the multiple battery packs BP. Specifically, the battery ECU 30 calculates the minimum value, here "5 kW", from among the charge power values "10 kW", "5 kW", ..., "8 kW".

Figure 3 is a diagram showing an example of the minimum value and the actual charging power. The battery ECU 30 calculates a first charging power value by multiplying the minimum value (see Figure 3) by the number of connections, which is the number of battery packs BP connected in parallel to the charger 1. Specifically, the battery ECU 30 calculates a first charging power value "n * 5 kW" by multiplying the minimum value "5 kW" by the number of connections n. For example, when the number of connections n is 3, the first charging power value is "15 kW".

The battery ECU 30 transmits the first charging power value to the control ECU 40. For example, if the number of connections n is 3, the battery ECU 30 transmits the first charging power value "15 kW" to the control ECU 40.

[Control ECU 40]
The control ECU 40 includes a central processing unit (CPU), a read only memory (ROM), a random access memory (RAM), etc. The CPU reads out a program corresponding to the processing contents from the ROM, loads it into the RAM, and executes a predetermined function of the control ECU 40 in cooperation with the loaded program. At this time, various data stored in a storage unit (not shown) is referenced. The storage unit is configured, for example, of a non-volatile semiconductor memory (so-called flash memory) or a hard disk drive. The control ECU 40 may be incorporated, for example, in a vehicle electronic control unit (ECU) that controls each part of the vehicle, may be configured integrally with the battery ECU 30, or may be provided separately from the vehicle ECU and the battery ECU 30.

The control ECU 40 transmits an instruction value based on the first charging power value to the charger 1. The charger 1 charges the battery pack BU with charging power based on the instruction value. As a result, the charging power value, which is the charging power actually charged to each of the battery packs BP1, BP2, and BP3 connected in parallel to the charger 1 and is detected by the monitoring unit 20 and is the numerical value of the charging power, is 4 [kW] (the numerical values of the charging power actually charged to the multiple battery packs BP may differ from each other, but here, for ease of explanation, they are assumed to be the same). The battery ECU 30 has a function (corresponding to the "second calculation unit" of this disclosure) to calculate a second charging capacity value, which is the sum of the numerical values of the charging power actually charged to the battery pack BU, based on the detected charging power value transmitted from the monitoring unit 20, and to calculate the difference between the calculated second charging power value (e.g., 12 kW) and the first charging power value (e.g., 15 kW = 5 kW * 3).

As described above, the first charging power value (e.g., 15 kW) and the second charging power value (e.g., 12 kW) may differ from each other due to electrical, thermal, or other reasons. When the second charging power value is lower than the first charging power value as in the embodiment, the charging time until the battery pack BP is fully charged becomes longer, and efficient charging is not possible. Conversely, when the second charging power value is higher than the first charging power value, overcharging may occur, and safety may not be guaranteed.

Therefore, in this embodiment, the battery ECU 30 calculates a second charging power value, which is the numerical value of the charging power with which the battery pack BU is actually charged, based on the detected charging power value transmitted from the monitoring unit 20, and calculates the difference between the calculated second charging power value and the first charging power value, and the control ECU 40 feeds the difference calculated by the battery ECU 30 to the instruction value.

Next, an example of a charge control method according to an embodiment of the present disclosure will be described with reference to FIG. 4. FIG. 4 is a flowchart showing an example of a charge control method according to an embodiment of the present disclosure. Note that each step shown in FIG. 4 will be described as being executed by the respective CPUs of the battery ECU 30 and the control ECU 40. Also, this flow is started, for example, when the battery pack BP is connected to the charger 1 and a charging start instruction is given by the user, and is then repeated at predetermined time intervals. At the start of charging, charging power is sent from the charger 1 to the electrical path 3 based on the instruction value. Also, the monitoring unit 20 detects the charging power with which the battery packs BP1, BP2, ..., BPn are actually charged at predetermined time intervals, and outputs the detected value to the battery ECU 30.

First, in step S100, the CPU calculates a first charging power value that is permissible for the battery pack BU based on the estimated charging power value transmitted from the monitoring unit 20.

Next, in step S110, the CPU transmits an instruction value based on the first charging power value to the charger 1.

Next, in step S120, the CPU calculates a second charging power value, which is the numerical value of the charging power with which the battery pack BU is actually charged, based on the detected charging power value transmitted from the monitoring unit 20, and further calculates the difference between the second charging power value and the first charging power value.

Next, in step S130, the CPU feeds back the difference to the instruction value. Then, this flow ends.

The charge control device 10 according to an embodiment of the present disclosure is a charge control device 10 in a power supply system having a battery pack BU composed of a plurality of battery packs BP connected in parallel to a charger 1, and includes an estimation unit that estimates a charging power value permitted by each of the plurality of battery packs BP, a first calculation unit that calculates a first charging power value that can be permitted for the battery pack BU based on the estimated charging power value, a control unit that instructs the charger 1 on an instruction value based on the calculated first charging power value, and a second calculation unit that calculates the difference between a second charging power value, which is a numerical value of the charging power with which the battery pack BU is actually charged, and the first charging power value when the charger 1 charges the battery pack based on the instruction value, and the control unit feeds back the difference to the instruction value.

With the above configuration, when the second charging power value is smaller than the first charging power value, the difference between the second charging power value and the first charging power value is fed back to the instruction value, thereby increasing the second charging power value, and thus making it possible to charge the battery pack BP efficiently. On the other hand, when the second charging power is larger than the first charging power, the difference between the second charging power value and the first charging power value is fed back to the instruction value, thereby decreasing the second charging power value, thereby making it possible to ensure safety.

The charging control device 10 according to the above embodiment is applied to a charging system in which a battery pack BP is connected to a charger 1 via an electrical path 3 (cable), but the present disclosure is not limited to this. For example, it may be applied to a non-contact charging system in which power is transmitted wirelessly between a power transmission coil on the charger 1 side and a power receiving coil on the vehicle side. In this case, the control ECU 40 transmits an instruction value wirelessly to the charger 1 side. The transmitted power is converted to direct current by an on-board rectifier before being supplied to the battery pack BP.

In the above embodiment, the present disclosure is applied to a charge control device that charges multiple battery packs BP connected in parallel to the charger 1, but it is not limited to this and may be applied to a charge control device that charges one battery pack BP connected to the charger 1. In this case, the charging power value permitted by the battery pack BP is estimated, and the charging power value permitted for the battery pack BP based on the estimated charging power value is set as a first charging power value, and the numerical value of the charging power with which the battery pack BP is actually charged is set as a second charging power value, and the difference between the second charging power value and the first charging power value is calculated, and the difference is fed back to the instruction value.

In addition, the above embodiments are merely examples of concrete ways of implementing the present disclosure, and the technical scope of the present disclosure should not be interpreted in a limiting manner based on them. In other words, the present disclosure can be implemented in various forms without departing from its gist or main features.

In addition, the above embodiments are merely examples of concrete ways of implementing the present disclosure, and the technical scope of the present disclosure should not be interpreted in a limiting manner based on them. In other words, the present disclosure can be implemented in various forms without departing from its gist or main features.

This disclosure is suitable for use in vehicles equipped with a charging control device that is required to efficiently charge a battery pack while ensuring safety.

BP, BP1, BP2, BPn Battery pack BU Assembled battery 1 Charger 3 Electrical path 3a Branch path 10 Charging control device 20 Monitoring unit 30 Battery ECU
40 Control ECU

Claims (5)

A charge control device in a power supply system having a battery pack connected to a charger,
an estimation unit that estimates a charging power value permitted by the battery pack;
a first calculation unit that calculates a first charging power value that is permissible for the battery pack based on the estimated charging power value;
a control unit that instructs the charger of an instruction value based on the calculated first charging power value;
a second calculation unit that calculates a difference between a second charging power value, which is a numerical value of charging power with which the battery pack is actually charged, and the first charging power value, when the charger charges the battery pack based on the instruction value;
Equipped with
the control unit sets the first charging power value as the instruction value when the first charging power value is greater than the second charging power value due to the difference, and sets the first charging power value as the instruction value when the second charging power value is greater than the first charging power value .
Charging control device. A charge control device in a power supply system having a battery pack composed of a plurality of battery packs connected in parallel to a charger,
an estimation unit that estimates a charging power value permitted for each of the plurality of battery packs;
a first calculation unit that calculates a first charging power value that is permissible for the battery pack based on the estimated charging power value;
a control unit that instructs the charger of an instruction value based on the calculated first charging power value;
a second calculation unit that calculates a difference between a second charging power value, which is a numerical value of charging power with which the battery pack is actually charged, and the first charging power value, when the charger charges the battery pack based on the instruction value;
Equipped with
the control unit sets the first charging power value as the instruction value when the first charging power value is greater than the second charging power value due to the difference, and sets the first charging power value as the instruction value when the second charging power value is greater than the first charging power value .
Charging control device. The charge control device according to claim 2, wherein the first charging power value is a numerical value obtained by multiplying the minimum of the charging power values permitted by each of the plurality of battery packs by the number of connections, which is the number of battery packs connected in parallel to the charger. The charge control device according to claim 2 or 3, wherein the second charging power value is a sum of the charging power values actually charged to each of the multiple battery packs connected in parallel to the charger. A charging control method in a power supply system having a battery pack composed of a plurality of battery packs connected in parallel to a charger, comprising:
estimating a charging power value permitted by each of the plurality of battery packs;
calculating a first charging power value that is permissible for the battery pack based on the estimated charging power value;
instructing the charger to set an instruction value based on the calculated first charging power value;
calculating a difference between a second charging power value, which is a numerical value of charging power with which the battery pack is actually charged, and the first charging power value, when the charger charges the battery pack based on the instruction value;
setting the first charging power value as the instruction value when the first charging power value is greater than the second charging power value according to the calculated difference, and setting the first charging power value as the instruction value when the second charging power value is greater than the first charging power value ;
Equipped with
Charging control method.