JPH0654196U - Power supply device consisting of battery pack and charger - Google Patents

Abstract

(57) [Abstract] [Purpose] Everyone should be able to use the battery easily and easily, regardless of the battery type. [Structure] A plurality of battery packs 1 having different types of built-in batteries, and a charger 3 for removably setting and charging the battery pack 1 are provided. The electrode terminals of the battery packs 1 having different types of built-in batteries are arranged side by side close to each other at different positions. The charger 3 includes a plurality of sets of charging terminals 4 for charging the battery packs 1 having different types of built-in batteries with different charging terminals 4. [Effect] Since battery packs of different models can be used in the same manner, they can be used very conveniently, and since the electrode terminals are brought close to each other, the terminal portion can be made compact.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a power supply device using battery packs having different types of built-in batteries, for example, nickel-cadmium secondary battery and lithium-ion secondary battery battery pack.

[0002]

[Prior art]

 Electric devices may use battery packs with different types of built-in batteries as power sources. For example, a battery pack containing a nickel-cadmium secondary battery and a battery pack containing a lithium-ion secondary battery may be used. In this case, the nickel-cadmium secondary battery and the lithium-ion secondary battery can be charged by different dedicated chargers. However, this method requires two dedicated chargers, which increases the cost of the charger and has the drawback that it cannot be used conveniently. Designing a single charger to charge battery packs with different types of built-in batteries will reduce the cost of the charger and make it convenient to use. In this case, it is necessary to charge battery packs with different types of built-in batteries under optimum conditions. For example, it is important to charge a nickel-cadmium secondary battery at a constant current and a lithium-ion secondary battery at a constant voltage. If the charging conditions are not adjusted optimally, battery performance may decline or overcharge may result in a dangerous condition.

In order to charge battery packs having different types of built-in batteries under different charging conditions, the conventional battery pack changes the positions of the electrode terminals 2 provided in the battery pack 1 according to the type of electrodes, as shown in FIG. is doing. For example, the battery pack 1 containing a nickel-cadmium secondary battery and the battery pack 1 containing a lithium-ion secondary battery have electrode terminals 2 at opposite positions. The charger for charging this battery pack has separate charging terminals for charging the nickel-cadmium battery pack and the lithium-ion battery pack.

[0004]

[Problems to be solved by the device]

 As shown in FIG. 1, a battery pack having an electrode terminal on the opposite side depending on the type of battery can be charged under optimum conditions for the built-in battery. For example, when a battery pack containing a lithium-ion secondary battery is set in the charger, the electrode terminals provided at the lower end are connected to the charging terminals of the charger. When the battery pack containing the nickel-cadmium secondary battery is set in the charger, the electrode terminals on the upper end are connected to the charging terminals of the charger. The charger has a charging terminal at the lower end for a lithium-ion secondary battery, and a charging terminal at the upper end for a nickel-cadmium secondary battery. The charger and battery pack with this structure can charge battery packs with different types of built-in batteries under optimum conditions. However, the battery pack with this structure needs to be turned upside down and set in the electric device depending on the type of electrode. This is because the electrode terminals are provided on the opposite side depending on the type of electrode. Therefore, there is a drawback that no one can use it easily. In addition, the shape of the part where the battery pack is set in the charger and the electric device needs to be a shape that allows the battery pack to be turned upside down, which makes it difficult to design this part. Further, the charger has a drawback that it becomes large because the charging terminals are provided on the upper part and the lower part.

The present invention was developed for the purpose of solving this drawback. An important object of the present invention is to provide a power supply device including a battery pack and a charger, which does not require the user to change the setting direction of the battery pack depending on the type of the battery and can be used simply and conveniently. . Another important object of the present invention is to provide a power supply device including a battery pack and a charger, which can simplify the structure of the terminal portion of the charger and the electric device and can be downsized.

[0006]

[Means for Solving the Problems]

 A power supply device including a battery pack and a charger according to the present invention has the following configuration in order to achieve the above object. The power supply device of the present invention comprises a plurality of battery packs 1 having different types of built-in batteries, and a charger 3 for removably setting and charging the battery packs 1. For the battery pack 1 having different types of built-in batteries, for example, a battery pack containing a lithium-ion secondary battery and a battery pack containing a nickel-cadmium secondary battery or a nickel-hydrogen nickel-cadmium battery can be used.

Further, the power supply device of the present invention is characterized in that the battery pack 1 and the charger 3 have the following configurations. (A) The battery pack 1 has the electrode terminal 2 connected to a built-in battery. (B) The battery packs 1 having different types of built-in batteries are provided with electrode terminals 2 at different positions in order to distinguish the built-in batteries and charge the built-in batteries under optimum conditions. (C) In the battery packs 1 having different types of built-in batteries, at least the portions set in the charger 3 have the same shape so that they can be set in the charger 3 and the electric device in the same direction. The battery packs 1 having different types of built-in batteries are preferably designed so that not only the shape of the portion to be set in the charger 3 but also the entire shape is the same. (D) The electrode terminals 2 of the battery pack 1 arranged at different positions are arranged close to each other depending on the type of the built-in battery of the battery pack 1. (E) The charger 3 includes a plurality of sets of charging terminals 4 for charging the battery packs 1 having different types of built-in batteries under optimum conditions for the built-in batteries. (F) The charging terminal 4 is arranged at a position in contact with the electrode terminal 2 of the battery pack 1 to be set. (G) The plurality of sets of charging terminals 4 are arranged close to each other so as to be connected to the electrode terminals 2 having different types of built-in batteries.

[0008]

[Action]

 The power supply device shown in FIG. 2 according to the preferred embodiment of the present invention is used in the following states. In this figure, the upper battery pack 1 is a battery pack containing a nickel-cadmium secondary battery or a nickel-hydrogen battery (hereinafter referred to as type 1 battery pack 1A in this specification), and the lower battery pack 1 is This is a battery pack 1 having a lithium ion secondary battery built-in (hereinafter, this electrode is referred to as a type 2 battery pack 1B). The electrode terminal 2A of the type 1 battery pack 1A is arranged inside the electrode terminal 2B of the type 2 battery pack 1B. On the other hand, the charger 3 is provided with two sets of charging terminals 4A and 4B so as to separately contact the electrode terminal 2A of the type 1 battery pack 1A and the electrode terminal 2B of the type 2 battery pack 1B. The charging terminal 4A of the type 1 battery pack 1A is arranged inside the charging terminal 4B of the type 2 battery pack 1B.

The type 1 battery pack 1A and the type 2 battery pack 1B are charged in the following states. State in which the type 1 battery pack 1A is set in the charger 3 The electrode terminal 2A of the type 1 battery pack 1A is connected to the charging terminal 4A of the charger 3. At this time, the charging terminal 4B of the type 2 battery pack 1B is at a position different from the electrode terminal 2A of the type 1 battery pack 1A, and this is not connected to the electrode terminal 2A of the type 1 battery pack 1A. Therefore, in this state, the type 1 battery pack 1A is charged with constant current under optimum conditions through the dedicated charging terminal 4 provided inside. State in which the type 2 battery pack 1B is set in the charger 3 The electrode terminal 2B of the type 2 battery pack 1B is connected to the charging terminal 4B of the charger 3 arranged outside. At this time, the charging terminal 4A of the type 1 battery pack 1A is at a position different from the electrode terminal 2B of the type 2 battery pack 1B, and this is not connected to the electrode terminal 2B of the type 2 battery pack 1B. Therefore, in this state, the type 2 battery pack 1B is subjected to constant voltage charging under optimum conditions via the dedicated charging terminal 4B arranged on the outside.

The charged type 1 battery pack 1A and type 2 battery pack 1B can be similarly set in an electric device and used. In particular, as shown in FIG. 3, by making the electrode terminals 2A and 2B of the type 1 battery pack 1A and the type 2 battery pack 1B partially in the same position, the electric device is It can be connected to a battery pack via a set of connection terminals 5. This is because the connection terminal 5 of the electric device can be connected to both the battery packs 1 by providing the connection terminals 5 at the electrode terminals 2A and 2B of both the type 1 battery pack 1A and the type 2 battery pack 1B. However, it goes without saying that the electric device may be provided with dedicated connection terminals that are separately connected to the electrode terminals 2A and 2B of the type 1 battery pack 1A and the type 2 battery pack 1B.

[0011]

【Example】

 Embodiments of the present invention will be described below with reference to the drawings. However, the embodiments described below exemplify a power supply device for embodying the technical idea of the present invention, and the power supply device of the present invention is configured with various types such as component types, shapes, circuit configurations, and layouts. Not specific to: The power supply device of the present invention can be modified in various ways within the scope of claims for utility model registration.

Further, in this specification, in order to facilitate understanding of the scope of claims for utility model registration, the numbers corresponding to the members shown in the examples are referred to as "column for claims for utility model registration" and "column for action". , And "members for solving the problems" are added. However, the members indicated in the claims for utility model registration are not specified as the members of the embodiment.

The power supply device shown in FIGS. 2 and 3 includes a plurality of battery packs 1 having different types of built-in batteries and a charger 3. The battery pack 1 includes a type 1 battery pack 1A containing a nickel-cadmium secondary battery or a nickel-hydrogen battery and a type 2 battery pack 1B containing a lithium-ion secondary battery. The built-in battery of the type 1 battery pack 1A is charged with constant current to be fully charged. The type 2 battery pack 1B is charged to a constant voltage and fully charged. However, in the type 2 battery pack 1B, the charging time can be shortened by performing constant current charging and then constant voltage charging after the battery voltage rises to a constant level.

The battery pack 1 contains a secondary battery (not shown) inside a casing. On the surface of the casing, positive and negative electrode terminals 2A and 2B are provided. The electrode terminals 2A and 2B are connected to a built-in battery (not shown) via lead wires (not shown). As shown in FIG. 2, the electrode terminals 2A and 2B are arranged at different positions in the type 1 battery pack 1A and the type 2 battery pack 1B. This is for connecting the electrode terminals 2A and 2B to different charging terminals 4A and 4B of the charger 3 in the type 1 battery pack 1A and the type 2 battery pack 1B. The electrode terminals 2A and 2B provided in the type 1 battery pack 1A and the type 2 battery pack 1B are arranged in close proximity to each other, although the positions are different, as shown by the solid line and the broken line in FIG. There is. In the type 1 battery pack 1A and the type 2 battery pack 1B shown in FIG. 2, the electrode terminals 2A and 2B are provided side by side with the center position separated by about 5 mm. The center distance (d) between the electrode terminals 2A and 2B arranged at different positions is preferably set in the range of 3 mm to 20 mm, more preferably 3 mm to 10 mm.

In the battery pack 1 shown in FIGS. 2 and 3, the electrode terminals 2A of the type 1 battery pack 1A are arranged inside the electrode terminals 2B of the type 2 battery pack 1B. Further, as shown in FIG. 3, the outer portion of the electrode terminal 2A of the type 1 battery pack 1A and the inner portion of the electrode terminal 2B of the type 2 battery pack 1B are arranged at the same position. In this way, when a part of the electrode terminals 2A and 2B arranged at different positions are arranged at the same position, the electric device has a single connection terminal 5 as a type 1 battery pack 1A and a type 2 battery pack. It has a feature that it can be connected to both electrode terminals 2A and 2B of 1B. For this reason, electrical equipment has the feature that connection terminals can be easily made.

The charger 3 includes a type 1 battery pack charging circuit 6 and a type 2 battery pack charging circuit 7 in order to charge the type 1 battery pack 1A and the type 2 battery pack 1B under optimum charging conditions. Further, the charging circuits 6 and 7 are provided with a power source 8 that supplies DC power as a predetermined voltage. The type 1 battery pack charging circuit 6 is designed to charge the type 1 battery pack 1A under optimum conditions. Since the type 1 battery pack 1A is a nickel-cadmium secondary battery or a nickel-hydrogen battery, it is charged with a constant current at a predetermined current and stops charging when the power source is fully charged. The type 2 battery pack charging circuit 7 charges the type 2 battery pack 1B containing a lithium-ion secondary battery under optimum conditions. The lithium-ion secondary battery is charged to a constant voltage, or charged to a constant current and then charged to a constant voltage to be fully charged.

As shown in FIG. 2, the charger 3 includes a type 1 charging terminal 4A and a type 2 charging terminal 4B for charging the type 1 battery pack 1A and the type 2 battery pack 1B under different conditions. 2 sets of charging terminals 4 composed of The two sets of charging terminals 4A and 4B are arranged close to each other, and the type 1 charging terminal 4A is arranged inside the type 2 charging terminal 4B. The type 1 charging terminal 4A is placed in contact with the electrode terminal 2A of the set type 1 battery pack 1A, and the type 2 charging terminal 4B is placed in contact with the electrode terminal 2B of the set type 2 battery pack 1B. To be done. The type 1 charging terminal 4A is connected to the type 1 battery pack charging circuit 6, and the type 2 charging terminal 4B is connected to the type 2 battery pack charging circuit 7.

The power supply device having this structure charges the battery pack 1 as follows. When charging the type 1 battery pack 1A When the type 1 battery pack 1A is set in the charger 3, the electrode terminal 2A of the type 1 battery pack 1A is connected to the type 1 charging terminal 4A. At this time, the type 2 charging terminal 4B is not connected to the electrode terminal 2A of the type 1 battery pack 1A. The battery pack 1 in which the electrode terminal 2A is connected to the type 1 charging terminal 4A is fully charged by the type 1 battery pack charging circuit 6. When charging the type 2 battery pack 1B When the type 2 battery pack 1B is set in the charger 3, the electrode terminal 2B of the type 2 battery pack 1B is connected to the type 2 charging terminal 4B. At this time, the type 1 charging terminal 4A is not connected to the electrode terminal 2B of the type 2 battery pack 1B. The battery pack 1 in which the electrode terminal 2B is connected to the type 2 charging terminal 4B is fully charged by the type 2 battery pack charging circuit 7.

FIG. 4 shows a battery pack mounting surface of an electric device in which the type 1 battery pack and the type 2 battery pack shown in FIG. 2 are set. On the mounting surface of the electric device shown in this figure, the connection terminal 5 is arranged at a position where it can contact both the type 1 charging terminal and the type 2 charging terminal. However, as shown by a broken line, dedicated connection terminals may be provided for the type 1 charging terminal and the type 2 charging terminal in close proximity to each other.

[0020]

[Effect of device]

 The battery pack of the present invention does not need to be used differently depending on the type of built-in electrode. Users can similarly use battery packs that incorporate various types of electrodes. For this reason, it has the feature that anyone can use it easily and conveniently without making a mistake in how to use it. This is because even if the power supply device of the present invention has battery packs with different types of built-in batteries, the shape of the part to be set in the charger is the same. This is because the built-in battery can be charged in the optimal state. Particularly, in the power supply device of the present invention, the electrode terminals of battery packs having different types of built-in batteries are arranged side by side but close to each other, so that the directions of the battery packs having different types of built-in batteries are changed. It can be set in the charger without charging, and it has the feature that it can be made compact at the charging terminal of the charger. This is because, unlike the conventional charger, it is not necessary to separately provide the charging terminals at the top and bottom, and a plurality of sets of charging terminals can be arranged side by side in close proximity. Furthermore, even if the type of built-in battery is different, the battery pack has electrode terminals that are close to each other, and the feature is that the connection terminals of electrical equipment can be made compact. This is because they can be connected to the electrode terminals of battery packs with different types of built-in batteries via connecting terminals that are close to each other. In particular, as shown in Fig. 2, a battery pack in which some of the electrode terminals are provided at the same position can be connected to an electric device through a single connection terminal, so the connection terminal of the electric device can be extremely There is a feature that can be simplified.

[Brief description of drawings]

FIG. 1 is a perspective view showing a conventional battery pack.

FIG. 2 is a perspective view of a power supply device showing an embodiment of the present invention.

FIG. 3 is a circuit diagram of the power supply device shown in FIG.

FIG. 4 is a front view showing an example of a surface on which a battery pack of an electric device is set.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Battery pack 1A ... Type 1 battery pack 1B ... Type 2 battery pack 2 ... Electrode terminal 3 ... Charger 4 ... Charging terminal 4A ... Charging terminal 4B ... Charging terminal 5 ... Connection terminal 6 ... Type 1 battery pack charging circuit 7 ... Type 2 battery pack charging circuit 8 ... Power supply

Claims (1)

[Scope of utility model registration request] 1. A battery pack comprising a plurality of battery packs (1) having different types of built-in batteries and a charger (3) for removably setting and charging the battery pack (1).
A power supply device characterized in that (1) and a charger (3) have the following configurations. (A) The battery pack (1) has an electrode terminal (2) connected to a built-in battery. (B) Battery pack with different type of built-in battery (1)
Are equipped with electrode terminals (2) at different positions. (C) Battery pack with different type of built-in battery (1)
Have the same shape at least in the part set in the charger (3). (D) The electrode terminals (2) of the battery pack (1) arranged at different positions are arranged close to each other depending on the type of the built-in electrodes of the battery pack (1). (E) The charger (3) has a plurality of sets of charging terminals (4) for charging battery packs (1) having different types of built-in batteries with different charging terminals (4). (F) The charging terminal (4) is arranged at a position in contact with the electrode terminal (2) of the battery pack (1) to be set. (G) The plurality of sets of charging terminals (4) are arranged close to each other so as to be connected to the electrode terminals (2) having different types of built-in batteries.