JP2020205667A - Charger - Google Patents

Abstract

To provide a charger capable of performing flexible charge control.SOLUTION: A charger 30 comprises: a power supply circuit 31 which charges a battery pack 10; a control unit 32 which acquires information of the battery pack 10 and controls the power supply circuit 31 based on the acquired information; a storage unit 33 which stores a first charge control property of the battery pack 10; and an Internet connection unit 34 communicable with a server 70. The control unit 32 is configured to acquire an optimal second charge control property based on the information of the battery pack 10 from the server 70 via the Internet connection unit 34 or a portable terminal 50. The control unit 32 is configured to select one of the first charge control property and the second charge control property as a charge control property of the battery pack 10.SELECTED DRAWING: Figure 1

Description

The present invention relates to a charging device for charging a battery pack.

The following Patent Document 1 discloses a charging device that changes the charging current based on the battery information from the battery pack.

JP-A-2015-180179

The charging device of Patent Document 1 can only charge with the charging control (charging current) stored by itself. Further, since the charging current follows a predetermined charging current during charging, the charging current cannot be set according to the state of the battery pack being charged.

The present invention has been made in recognition of such a situation, and an object of the present invention is to provide a charging device capable of flexible charge control.

One aspect of the present invention is a charging device. This charging device
The charging circuit that charges the battery pack and
The acquisition unit that acquires the information of the battery pack and
A control unit that controls the charging circuit unit based on the information of the battery pack,
Equipped with a communication unit that can communicate with an external computer
The acquisition unit stores the first charge control characteristic of the battery pack, and stores the first charge control characteristic.
The communication unit is configured to be able to acquire the optimum second charge control characteristic based on the information of the battery pack from the external computer.
The control unit is configured to be able to select one of the first charge control characteristic and the second charge control characteristic as the charge control characteristic of the battery pack.

The control unit may be configured to charge the battery pack with the first charge control characteristic when the external computer is not connected to the communication unit.

The control unit may be configured to automatically select the charge control characteristics of the battery pack.

The communication unit is configured to be capable of wireless communication with the external computer.
The control unit may be configured to automatically select the charge control characteristic of the battery pack according to the state of the wireless communication.

The control unit may be configured to charge the battery pack with the first charge control characteristic when the wireless communication is impossible or the radio wave of the wireless communication is weak.

The information includes a usage history of the battery pack.
The communication unit may be configured to be able to acquire the optimum second charge control characteristic from the external computer based on the usage history of the battery pack.

The control unit may sequentially acquire information on the battery pack while charging the battery pack, and set the charging current of the battery pack based on the acquired information.

Another aspect of the present invention is a charging device. This charging device
The charging circuit that charges the battery pack and
The acquisition unit that acquires the information of the battery pack and
A control unit that controls the charging circuit unit based on the information of the battery pack is provided.
The control unit sequentially acquires information on the battery pack while charging the battery pack, and sets the charging current of the battery pack based on the acquired information.

The information of the battery pack acquired during charging may include the voltage of each cell of the battery pack.

It should be noted that any combination of the above components and a conversion of the expression of the present invention between methods, systems and the like are also effective as aspects of the present invention.

According to the present invention, it is possible to provide a charging device capable of flexible charging control.

FIG. 6 is a schematic block diagram of a charger (charging device) 30 according to an embodiment of the present invention and a charging system including the same. The flowchart of the data update in the charger 30. The flowchart of the charging operation in the charger 30. The table which shows an example of the information which the charger 30 acquires from the battery pack 10. A table showing an example of an input vector and a weighting vector used by the charger 30 for calculating the charging current. Flow chart of calculation and update of charging current by charger 30. The graph which showed the example of the time change of the charging current in the charger 30 for each of the cases where the battery pack 10 was charged once, 500 times, and 1000 times.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings. The same or equivalent components, members, processes, etc. shown in the drawings are designated by the same reference numerals, and redundant description will be omitted as appropriate. Moreover, the embodiment is not limited to the invention but is an example, and all the features and combinations thereof described in the embodiment are not necessarily essential to the invention.

The present embodiment relates to a charger (charging device) 30 and a charging system including the charger (charging device) 30. As shown in FIG. 1, this charging system includes a battery pack 10, a charger 30, a mobile terminal 50 such as a smartphone, and a server (external computer) 70. The battery pack 10 and the charger 30 are electrically connected to each other by contact between the physical connection terminals. The charger 30 and the mobile terminal 50 can communicate with each other. Specifically, the charger 30 and the mobile terminal 50 are connected by a communication cable to enable wired communication with each other, or wirelessly communicate with each other using Bluetooth (registered trademark) or wireless LAN (Wireless Local Area Network). It is possible. The mobile terminal 50 is connected to the server 70 via a network such as the Internet. The charger 30 is connected to the server 70 via a network such as the Internet.

The battery pack 10 has a storage unit (battery side storage unit) 11, a control unit (battery side control unit) 12, and a battery cell 13. The storage unit 11 stores the information of the battery pack 10. This information includes the usage history of the battery pack 10. As illustrated in FIG. 4, the information stored in the storage unit 11 includes the number of charges (cumulative number of charges), the number of overcharge detections, the number of overdischarge detections, the number of overcurrent detections, and the battery cell 13. It includes the voltage of the cell, the temperature of the battery cell 13, the type of electric device such as a tool used by connecting the battery pack 10, the usage time of each electric device, and the like. The control unit 12 has a communication function of reading the information stored in the storage unit 11 and transmitting the information to the charger 30 via the physical connection terminal, and when overcharge is detected, charging is stopped, overdischarge is detected, or overcurrent is detected. It has a protective function to stop the discharge. The battery cell 13 includes a plurality of secondary battery cells such as a lithium battery. The control unit 12 can detect the voltage of each cell of the battery cell 13 and store it in the storage unit 11 or transmit it to the charger 30.

The charger 30 includes a power supply circuit 31 (charging circuit unit), a control unit (charger side control unit) 32, a storage unit (charger side storage unit) 33, an Internet connection unit (network connection unit) 34, and the like. Has. The power supply circuit 31 converts the supply voltage from the external AC power supply into the charging voltage of the battery pack 10. The control unit 32 has a communication function (function as an acquisition unit) for receiving information on the battery pack 10 from the control unit 12 of the battery pack 10 via a physical connection terminal, and a communication function for communicating with the mobile terminal 50 by wire or wirelessly (function as an acquisition unit). It has a function as a communication unit) and a charge control function for controlling the charge current of the battery pack 10 by controlling the power supply circuit 31. The storage unit 33 stores the charge control characteristics (first charge control characteristics) of the battery pack 10 for each type of battery pack 10 that can be charged by the charger 30.

The charge control characteristic is firmware data (program or calculation model) necessary for determining (calculating) the charging current of the battery pack 10 from the information of the battery pack 10, and includes a weighting vector and the like described later for each information. The control unit 32 can determine the charging current of the battery pack 10 based on the information of the battery pack 10 and the charge control characteristics stored in the storage unit 33. The Internet connection unit 34 has a communication function of connecting to the server 70 via a network such as the Internet and communicating with the server 70. When the charger 30 connects to the server 70 via the mobile terminal 50, the Internet connection unit 34 may be omitted from the charger 30. When the charger 30 has its own Internet connection unit 34 and connects to the server 70, the mobile terminal 50 may be omitted from the charging system of FIG.

The mobile terminal 50 includes a wireless communication unit 51, a control unit (mobile terminal side control unit) 52, a storage unit (mobile terminal side storage unit) 53, a user interface 54, and an Internet connection unit (network connection unit) 55. ,including. The wireless communication unit 51 has a wireless communication function with the charger 30. The control unit 52 controls the overall operation of the mobile terminal 50. The storage unit 53 stores various information. The user interface 54 displays a screen or the like for the user. The Internet connection unit 55 has a communication function of connecting to the server 70 via a network such as the Internet and communicating with the server 70.

The server 70 includes an information database (server-side storage unit) 71, an information processing unit (server-side control unit) 72, and an Internet connection unit (network connection unit) 73. The information database 71 stores the charge control characteristics (second charge control characteristics) of the battery pack 10 for each type of the battery pack 10. The charge control characteristic stored in the information database 71 is different from the charge control characteristic stored in the storage unit 33 of the charger 30 in that the charge control characteristic is constantly updated to the latest (optimal) charge control characteristic. For example, if a more appropriate weighting vector is found in the research process, or if the information of the battery pack 10 used for determining the charging current and the weighting vector for the information are added, the charge control characteristics of the information database 71 are immediately updated. To. The charge control characteristic stored in the storage unit 33 of the charger 30 does not correspond to the change of the weight vector or the addition of information until it is updated by the communication with the server 70.

FIG. 2 is a flowchart of data update in the charger 30. By executing this flowchart, the charge control characteristic stored in the storage unit 33 becomes the latest version. The communication between the charger 30 and the server 70 in FIG. 2 may be via the mobile terminal 50 or may be direct communication without the mobile terminal 50. When the control unit 32 is started, it transmits a connection request to the server 70 (S1). If there is a connectable response from the server 70 (“OK” in S3), the control unit 32 inquires the server 70 of the presence / absence of update data of the charge control characteristic (S5). At the time of inquiry, the information of the battery pack 10 connected to the charger 30 is transmitted. If there is update data (“Yes” in S7), the control unit 32 receives the update data from the server 70 and updates the charge control characteristics stored in the storage unit 33 with the update data (S9). The control unit 32 waits when the connection to the server 70 cannot be established (“No” in S3) and when there is no update data (“None” in S7).

FIG. 3 is a flowchart of the charging operation in the charger 30. When the battery pack 10 is connected to the charger 30, the control unit 32 shifts to the charging mode (S13). The control unit 32 transmits an information request to the battery pack 10 to acquire the information of the battery pack 10 (S15). An example of the acquired information is shown in FIG. The control unit 32 calculates the charging current based on the acquired information on the battery pack 10 and the charge control characteristics of the battery pack 10 (S17). As shown in FIG. 5, the weighting vector as the charge control characteristic is determined for each information of the battery pack 10. As the charge control characteristic, the control unit 32 uses the update data (second charge control characteristic) when the update data can be received from the server 70, and stores the update data in the storage unit 33 when the update data cannot be received from the server 70. The charged charge control characteristic (first charge control characteristic) is used. As a case where the control unit 32 uses the charge control characteristic stored in the storage unit 33, for example, when the charger 30 is far from the mobile terminal 50 and short-range wireless communication cannot be performed or the radio wave of short-range wireless communication is weak. , The charger 30 and / or the mobile terminal 50 may not be able to connect to the server 70 because it is out of the range of the network service. It is desirable that the control unit 32 automatically selects the charge control characteristic according to the communication state with the server 70. The control unit 32 sets the calculated charging current to the charging current of the battery pack 10 (S19). The control unit 32 repeats the steps S15, S17, and S19 periodically (for example, every 5 ms) until the voltage of the battery pack 10 exceeds the charge completion voltage (S21). The control unit 32 completes charging when the voltage of the battery pack 10 exceeds the charging completion voltage.

FIG. 4 is a table showing an example of information acquired by the charger 30 from the battery pack 10. FIG. 5 is a table showing an example of an input vector and a weighting vector used by the charger 30 for calculating the charging current. The weighting vector shown in FIG. 5 is received from the server 70 or stored in the storage unit 33 as a charge control characteristic. The cell balance shown in FIG. 5 indicates the variation in the voltage of each cell, and is derived by the control unit 32 based on the voltage of each cell received from the battery pack 10. The cell balance may be derived on the battery pack 10 side and transmitted to the charger 30. FIG. 6 is a flowchart for calculating and updating the charging current by the charger 30. The control unit 32 generates the input vector x shown in FIG. 5 based on the information of the battery pack 10 (S25). The control unit 32 multiplies the coefficient f (x, w) specified by the input vector x and the weighting vector w by the standard current value to derive the charging current (S27). The standard current value is, for example, the charging current when the number of times the battery pack 10 is charged is 0, there is no abnormality, the temperature is not high, and the cell voltage does not vary. f (x, w) is basically a value smaller than 1. The larger the number of charges, the number of various abnormalities (overcharge, overdischarge, overcurrent), the variation in cell voltage, and the value of cell temperature, the smaller f (x, w) and the smaller the charging current. The control unit 32 sets the derived charging current as the charging current of the battery pack 10 and charges the battery pack 10 (S29).

FIG. 7 is a graph showing an example of the time change of the charging current in the charger 30 for each of the cases where the battery pack 10 is charged once, 500 times, and 1000 times. This graph shows that the charging current of the battery pack 10 changes sequentially with the passage of time, and that the charging current decreases as the number of times the battery pack 10 is charged increases. The reason why the charging current changes sequentially is that the control unit 32 sequentially acquires the information of the battery pack 10 while charging the battery pack 10, and sets (sequentially updates) the charging current of the battery pack 10 based on the acquired information. is there. It is the voltage, cell balance, and cell temperature of each cell of the battery pack 10 that affects the change in charging current over time, and that information needs to be acquired or calculated sequentially during charging, but other things. It is enough to receive the information once at the start of charging.

According to this embodiment, the following effects can be obtained.

(1) If the control unit 32 of the charger 30 can receive the update data of the charge control characteristic from the server 70, the battery pack 10 is charged by the charge control characteristic received from the server 70, so that the memory of the charger 30 is stored. Compared with the case where only charging with the charging control characteristics stored in the unit 33 can be performed, flexible and optimum charging control becomes possible.

(2) If the control unit 32 automatically selects the charge control characteristic according to the communication state with the server 70, the user does not need to select the charge control characteristic and communicates without any particular consciousness. If the condition is good, the battery pack 10 is charged according to the charge control characteristic received from the server 70, which is highly convenient.

(3) The control unit 32 acquires the information of the battery pack 10 in real time while charging the battery pack 10, and sets (sequentially updates) the charging current of the battery pack 10 in real time based on the acquired information, so that it is determined in advance. Compared with the case where the charging current is changed stepwise according to the pattern, flexible and optimum charging control according to the state of the battery pack 10 being charged becomes possible.

Although the present invention has been described above by taking the embodiment as an example, it will be understood by those skilled in the art that various modifications can be made to each component and each processing process of the embodiment within the scope of the claims. By the way.

10 Battery pack, 11 Storage unit (battery side storage unit), 12 Control unit (battery side control unit), 13 Battery cell,
30 Charger, 31 Power supply circuit (Charging circuit unit), 32 Control unit (Charger side control unit), 33 Storage unit (Charger side storage unit), 34 Internet connection unit (Network connection unit),
50 mobile terminal (smartphone), 51 wireless communication unit, 52 control unit (mobile terminal side control unit), 53 storage unit (mobile terminal side storage unit), 54 user interface, 55 Internet connection unit (network connection unit),
70 Server (external computer), 71 Information database (server-side storage unit), 72 Information processing unit (server-side control unit), 73 Internet connection unit (network connection unit)

Claims (9)

The charging circuit that charges the battery pack and
The acquisition unit that acquires the information of the battery pack and
A control unit that controls the charging circuit unit based on the information of the battery pack,
Equipped with a communication unit that can communicate with an external computer
The acquisition unit stores the first charge control characteristic of the battery pack, and stores the first charge control characteristic.
The communication unit is configured to be able to acquire the optimum second charge control characteristic based on the information of the battery pack from the external computer.
The control unit is a charging device configured so that one of the first charge control characteristic and the second charge control characteristic can be selected as the charge control characteristic of the battery pack. The charging device according to claim 1, wherein the control unit is configured to charge the battery pack with the first charge control characteristic when the external computer is not connected to the communication unit. The charging device according to claim 1 or 2, wherein the control unit is configured to automatically select the charging control characteristics of the battery pack. The communication unit is configured to be capable of wireless communication with the external computer.
The charging device according to claim 3, wherein the control unit is configured to automatically select the charging control characteristics of the battery pack according to the state of the wireless communication. The charging device according to claim 4, wherein the control unit is configured to charge the battery pack with the first charge control characteristic when the wireless communication is impossible or the radio wave of the wireless communication is weak. The information includes a usage history of the battery pack.
The charging device according to any one of claims 1 to 5, wherein the communication unit is configured to be able to acquire the optimum second charging control characteristic from the external computer based on the usage history of the battery pack. The charging according to any one of claims 1 to 6, wherein the control unit sequentially acquires information on the battery pack while charging the battery pack, and sets the charging current of the battery pack based on the acquired information. apparatus. The charging circuit that charges the battery pack and
The acquisition unit that acquires the information of the battery pack and
A control unit that controls the charging circuit unit based on the information of the battery pack is provided.
The control unit is a charging device that sequentially acquires information on the battery pack while charging the battery pack and sets the charging current of the battery pack based on the acquired information. The charging device according to claim 7 or 8, wherein the information of the battery pack acquired during charging includes a voltage of each cell of the battery pack.

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