JPH03139128A - Multipack charger - Google Patents

Abstract

PURPOSE:To supply an optimum charging current to each battery pack when secondary battery packs are simultaneously charged by detecting the type of the secondary packs of two or more types having different capacities, generating the current responsive to the detected type, and charging the corresponding pack. CONSTITUTION:A reference battery pack and a large-capacity battery pack having different capacities are respectively connected to secondary battery packs 2. A detector 3 detects the type of the pack 2 connected to a connector 1, and a current controller 4 generates a charging current responsive to the type of the pack 2 based on the detected result. In this case, the controller 4 generates the current responsive to the capacity of the reference pack and the current responsive to the large-capacity pack, and a charger 5 supplies the generated current to the corresponding pack 2. Thus, when the packs of two or more types having different capacities are simultaneously charged, optimum currents can be supplied to the respective packs 2.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Field of Application J This invention relates to a multi-pack charger that charges a plurality of secondary battery packs, respectively.

[Invention i! i Essential] This invention detects the type of secondary battery pack so that two or more types of secondary battery packs with different capacities can be charged at the same time, and generates a charging TL flow according to the detected type. It is designed to charge a corresponding secondary battery pack.

[Prior Art] Conventionally, a charging device called a multi-pack charger charges a plurality of secondary battery packs of the same capacity at the same time. In other words, as battery packs that can be charged simultaneously, one type of battery pack with the same capacity was targeted.

[Problem to be solved by the invention J] For this reason, conventionally, in electronic equipment that selectively uses two types of battery packs with different capacities, it is necessary to prepare two types of multi-pack chargers according to the battery packs. For example, 5 lIRs? 1! ! It was necessary to prepare a multi-pack charger for standard batteries to charge battery packs at the same time and a multi-pack charger for large-capacity batteries to charge five large-capacity battery packs at the same time.

In order to efficiently charge a plurality of battery packs in this way, it is necessary to prepare a plurality of multi-pack chargers depending on the type of battery pack, which is uneconomical.

Therefore, 2 different capacities! When charging secondary battery packs of type II or higher at the same time, if the optimal charging current can be supplied to each battery pack, it will be possible to efficiently charge two types of battery packs with one charger.
Moreover, it is clear that it is also economically efficient.

An object of the present invention is to provide an optimal charging current to each battery pack when charging two or more types of secondary battery packs with different capacities at the same time.

[Means to solve the problem J The means of this invention are as follows.

The connection part l (see the block diagram in Figure 1, the same applies hereinafter) is
Secondary battery bank 2 of two or more types with different capacities...
・is electrically connected.

The detection section 3 detects the type of the secondary battery pack 2 connected to the connection section l.

The current control section 4 generates a charging current according to the type of each secondary battery pack 2 based on the detection result of the detection section 3 .

The charging section 5 supplies the charging current generated by the current control section 4 to the corresponding secondary battery pack 2 to charge it.

Now, in order to simultaneously charge two types of secondary battery packs 2, a standard battery pack and a large-capacity battery pack, PI semi-main battery packs and large-capacity battery packs with different capacities are connected to the secondary battery pack 2, respectively.

Then, the detection unit 3 detects the type of the secondary battery pack 2 connected to the connection unit l, and the current control unit 4 performs charging according to the type of each secondary battery pack 2 based on the detection result of the detection unit 3. f
t-flow is generated. In this case, the current control unit 4 generates a charging current according to the capacity of the standard battery pack and a charging current according to the capacity of the large-scale battery pack. Thereby, the charging section 5 supplies the charging current generated by the current control section 4 to the corresponding secondary battery pack 2 to charge it.

Therefore, when charging two or more types of secondary battery packs with different capacities at the same time, an optimal charging current can be supplied to each battery pack.

[Example J Hereinafter, one embodiment will be described with reference to FIGS. 2 to 5.

Figure 2 is a schematic perspective view of the multi-pack charger. Two types of secondary battery packs with different capacities (a standard battery pack and a large-capacity battery pack) are electrically connected to the charger body 11. Connector part 12A, 1 to be connected
2B is provided. Note that 5 connector parts 12A, 12
B may connect either a standard battery pack or a large capacity battery pack.

Fig. 3 is an internal configuration diagram of the standard battery pack 13, and the pack case 13a has a plurality of secondary batteries (including cadmium batteries) inside the pack case 13a.
The pack case 13a has three terminals 13PT exposed to the outside.
, 13NT, and 13DT are installed. here,
The terminal 13PT is a positive terminal connected to the positive electrode of the assembled battery 13b, the terminal 13NT is a negative terminal connected to the negative electrode of the assembled battery 13b, and the terminal 13DT is a detection terminal for detecting the type of battery pack. It is connected to the negative electrode of 13b.

FIG. 4 is an internal configuration diagram of the large-capacity battery pack 14. Inside the pack case 14a, there is provided a battery pack 14b consisting of a plurality of secondary batteries and cadmium batteries connected in series.
The pack case 14a has two terminals 14 exposed to the outside.
FT and 14NT are installed.

Therefore, the mark? l! ! The battery pack 13 has a detection terminal 13
Although the large-capacity battery pack 14 has a configuration including a DT, it does not have this type of detection terminal.

FIG. 5 is a circuit block diagram of the multi-pack charger.

The connector 12A is provided with three terminals, a positive terminal APT, a negative terminal ANT, and a detection terminal ADT, and the detection terminal ADT is connected to the high potential VCC from the pack capacity detection section 15A.
is applied. Similarly, the connector 12B is provided with three terminals, a positive terminal BPT, a negative terminal BNT, and a detection terminal BDT, and a high potential VCC is applied to the detection terminal BDT from the pack capacity detection section 15B.

Connector 1 corresponding to pack capacity detection units 15A and 15B
The type of secondary battery pack connected to 2A and 12B is detected, and the detection signal is given to the current control section 16.

The current control u4 unit 16 generates two types of charging current using a resistor etc. based on AC 100V, and also receives detection signals from the pack capacity detection units 15A and 15B to change the switch to generate two types of charging current. It is configured to output selectively.

Two types of charging currents selectively output from this current control section 16 are applied to corresponding charging sections 17A and 17B.

The charging parts 17A and 17B charge the corresponding battery packs while controlling the amount of current per unit time, and the charging current output from the charging parts 17A and 17B is connected to the corresponding backflow prevention diodes 18A and 18B. It is supplied to connectors 12A and 12B via the connector.

Next, the operation of this embodiment will be explained.

Now, assume that the standard battery pack 13 is connected to the connector 12A, and the large capacity battery pack 14 is connected to the connector 12B.

In this case, when the standard battery pack 13 is connected to the connector 12A, each terminal APT, ANT, AD of the connector 12A
T is the corresponding terminal 13PT of the standard battery pack 13, 1
3NT and 13DT are connected. At this point, connector 1
The 2A detection terminal ADT is the detection terminal 13 of the standard battery pack 13.
Since it is connected to the negative electrode of the assembled battery 13b via the DT, the detection signal output from the pack capacity detection section 15A becomes low level.

On the other hand, when the large capacity battery pack 14 is connected to the connector 12B, the corresponding terminals 14PT and 14NT of the large capacity battery pack 14 are connected to the terminals BPT and BNT of the connector 12B. In this case, since the large-capacity battery pack 14 is not provided with a detection terminal unlike the standard battery pack 13, the detection terminal BDT is electrically cut off, and the detection signal output from the pack capacity detection section 15B is high. level.

Therefore, the current control unit 16 sends the smaller charging current to the charging part 17A of the two types of charging current generated based on AClooV, and sends the larger charging current to the charging part 17B.
supply to. This increases the charging current in the TrL section 17A.
, 17B charge the corresponding standard battery pack 13 and large capacity battery pack 14.

On the other hand, when the large capacity battery pack 14 is connected to the connector 12A and the standard battery pack 13 is connected to the connector 12B, a high level detection signal is output from the pack capacity detection section 15A, and a low level detection signal is output from the pack capacity detection section 15B. Therefore, in this case, charging is performed in the opposite manner to that described above.

Although the above embodiment has a configuration in which two connectors 12A and 12B are provided, three or more connectors may be provided.

[Effects of the Invention] When charging two or more types of secondary battery packs with different capacities at the same time, this invention can supply an optimal charging current to each battery pack, so it is possible to supply two or more rechargeable battery packs with one charger.
This makes it possible to charge various types of battery packs efficiently, making it highly economical.

[Brief explanation of the drawing]

FIG. 1 is a block diagram of the present invention, FIGS. 2 to 5 show an embodiment, FIG. 2 is an external perspective view showing an outline of a multi-pack charger, and FIG. 3 is an internal configuration diagram of a standard battery pack 13. , FIG. 4 is an internal configuration diagram of the large capacity battery pack 14, and FIG. 5 is a block circuit diagram of the multi-pack charger. 12A, 12B... Connector, 13...
・Standard battery pack, 13PT, 14PT...Positive terminal, 13NT, 14NT...Minus terminal, 13DT...Detection terminal, 14...
Large capacity battery pack, 15A, 15B...Pack 8 Bar detection section, 16...Current control section, 17A, 1
7B...Charging part. Diagram

Claims (1)

[Scope of Claim] A multi-pack charger that charges a plurality of secondary battery packs, comprising: a connection part to which two or more types of secondary battery packs having different capacities are electrically connected; a detection unit that detects the type of secondary battery pack; a current control unit that generates a charging current according to the type of each secondary battery pack based on the detection result of this detection unit; A multi-pack charger characterized by comprising: a charging section that supplies charging current to a corresponding secondary battery pack to perform charging;