JP2018037392A - Battery pack and discharge plug - Google Patents

Abstract

PROBLEM TO BE SOLVED: To allow for fast charge of multiple secondary cells without having a heat dissipation mechanism or a heat dissipation structure in the current path, in a battery pack where a discharge path and a charge path are switched using a discharge plug and a charge plug.SOLUTION: A battery pack 11 includes first and second batteries B, B, first through fourth battery connection terminals T-Tconnected, respectively, with corresponding poles of the first and second batteries B, B, and first and second load connection terminals T, Tof respective poles connected with the load. Relation of connection of the first through fourth battery connection terminals T-Tand first and second load connection terminals T, Tis changed so that when the first and second batteries B, Bare discharged to the load 14, the load 14 is connected with the first and second batteries B, Bconnected in parallel, when the first and second batteries B, Bare charged, the first and second batteries B, Bare connected in series, and the first and second load connection terminals T, Thave the same potential.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a battery pack and a discharge plug.

  There is a battery pack that is mounted on a device together with a load, and a discharge path from a secondary battery in the battery pack to the load and a charge path from a charger to the secondary battery are switched using a discharge plug and a charge plug. Such a charge pack may include a plurality of secondary batteries connected in parallel in order to lengthen the dischargeable time to the load.

  As a related technique, a technique described in Patent Document 1 is known.

JP-A 64-24370

  However, in the battery pack as described above, in order to quickly charge a plurality of secondary batteries connected in parallel, a charging path from the charger to the plurality of secondary batteries (specifically, each of the battery connected in parallel It is necessary to flow a large current through a charging path where currents supplied to the secondary battery merge. As a result, the current path (for example, cable, bus bar, etc.) that becomes the charging path needs to have a heat dissipation mechanism or a heat dissipation structure to cope with a large current during charging, which increases the size and manufacturing cost of the battery pack. To do.

  An object of one aspect of the present invention is to quickly charge a plurality of secondary batteries without having a heat dissipation mechanism or a heat dissipation structure in a current path in a battery pack in which a discharge path and a charge path are switched using a discharge plug and a charge plug. Is to be able to do it.

  A battery pack according to one embodiment of the present invention includes a first battery, a second battery, a first battery connection terminal, a second battery connection terminal, a third battery connection terminal, and a fourth battery connection terminal. , A first load connection terminal, and a second load connection terminal. The first battery connection terminal is connected to one pole of the first battery, and the second battery connection terminal is connected to the other pole of the first battery. The third battery connection terminal is connected to one pole of the second battery, and the fourth battery connection terminal is connected to the other pole of the second battery. The first load connection terminal is a connection terminal of one pole connected to the load, and the second load connection terminal is a connection terminal of the other pole connected to the load.

  When the first battery and the second battery are discharged to the load, the first battery and the second battery are connected in parallel, and the load is connected to the first battery and the second battery connected in parallel. As described above, the connection relationship between the first to fourth battery connection terminals and the first and second load connection terminals is changed. Further, when the first battery and the second battery are charged, the first battery and the second battery are connected in series, and the first load connection terminal and the second load connection terminal have the same potential. Thus, the connection relationship between the first to fourth battery connection terminals and the first and second load connection terminals is changed.

  According to the battery pack according to one embodiment, a plurality of secondary batteries can be rapidly charged without having a heat dissipation mechanism or a heat dissipation structure in the current path.

It is a figure which shows the 1st structural example of the charging / discharging system containing the battery pack and discharge plug according to embodiment. It is a figure which shows the 2nd structural example of the charging / discharging system containing the battery pack and discharge plug according to embodiment. It is a figure which shows the 3rd structural example of the charging / discharging system containing the battery pack and discharge plug according to embodiment. It is a figure which shows the 4th structural example of the charging / discharging system containing the battery pack and discharge plug according to embodiment. It is a figure which shows the 5th structural example of the charging / discharging system containing the battery pack and discharge plug according to embodiment. It is explanatory drawing of the connection order of each terminal of the battery pack and discharge plug in a 5th structural example. It is a figure which shows the 6th structural example of the charging / discharging system containing the battery pack and discharge plug according to embodiment. It is a figure which shows the 7th structural example of the charging / discharging system containing the battery pack and discharge plug according to embodiment.

Hereinafter, embodiments will be described in detail with reference to the drawings.
<First configuration example>
FIG. 1 is a diagram illustrating a first configuration example of a charge / discharge system including a battery pack and a discharge plug according to the embodiment. As shown in FIG. 1, the charge / discharge system 1 includes a battery pack 11, a discharge plug 12, a charge plug 13, a load 14, and a charger 15.

  The battery pack 11 is mounted on an arbitrary device (not shown) together with the load 14. The device on which the battery pack 11 and the load 14 are mounted may be a vehicle (for example, an electric vehicle, a hybrid vehicle, or an electric forklift), and the load 14 may be a motor generator or a DC / DC (Direct Current / Direct Current). ) A converter may be used.

The battery pack 11 includes a first battery _{B 1} and the second battery _{B 2.} The battery pack 11 also includes a first battery connection terminal T _B1 , a second battery connection terminal T _B2 , a third battery connection terminal T _B3 , and a fourth battery connection terminal T _B4 . Furthermore, the battery pack 11 includes a first load connection terminal T _L1 and a second load connection terminal T _L2 .

The first battery B ₁ and the second battery B ₂ are each, for example, one or more secondary battery cells such as lithium ion battery or a lead acid battery.
The first battery connection terminal T _B1, the first one pole of the battery B ₁ (in FIG. 1, the positive terminal) is connected to. Second battery connection terminal T _B2, the first battery B ₁ of the other pole (in FIG. 1, the negative terminal) is connected to. The third battery connection terminal T _B3 is (in FIG. 1, the positive terminal) one pole of the second battery B ₂ is connected to. Battery connection terminal T _B4 of the fourth, the second battery B ₂ of the other pole (in FIG. 1, the negative terminal) is connected to.

The first load connection terminal T _L1 is a connection terminal of one pole (for example, positive electrode) connected to the load 14. The second load connection terminal T _L2 is a connection terminal of the other pole (for example, a negative electrode) connected to the load 14. Further, as can be understood from a comparison with the second configuration example shown in FIG. 2 and the third configuration example shown in FIG. 3, in the first configuration example shown in FIG. 1, the second battery connection terminal TB _{2 is used.} the combines second load connection terminal _{T L2,} the third battery connection terminal _{T B3} combine first load connection terminal _{T L1.} Therefore, the second battery connection terminal T _B2 is connected to the first battery B ₁ of the other pole and the load 14. The third battery connection terminal T _B3 is connected to the second one pole of the battery B ₂ and the load 14.

Next, the discharge plug 12 includes a first discharge plug terminal T _DC1 , a second discharge plug terminal T _DC2 , a third discharge plug terminal T _DC3 , and a fourth discharge plug terminal T _DC4 . The discharge plug 12 includes a first jumper line _{J 1} and the second jumper line _{J 2.}

When the discharge plug 12 is connected to the battery pack 11, the first discharge plug terminal T _DC1 is connected to the first battery connection terminal _TB1 , and the second discharge plug terminal T _DC2 is connected to the second battery connection terminal T. Connected to _B2 . The third discharge plug terminal _{T DC3} is connected to the third battery connection terminals _{T B3,} a fourth discharge plug terminals _{T DC4} is connected to the fourth battery connection terminal _{T B4.}

First jumper line _{J 1} is connected to the first discharge plug terminal _{T DC1} and the third discharge plug terminal _{T DC3.} The second jumper line _{J 2} is connected to the second discharge plug terminal _{T DC2} and the fourth discharge plug terminal _{T DC4.}

Next, the charging plug 13 includes a first charging plug terminal T _C1 , a second charging plug terminal T _C2 , a third charging plug terminal T _C3 , and a fourth charging plug terminal T _C4 . The first charging plug terminal _TC1 is a connection terminal of one pole (positive electrode in FIG. 1) on the charger 15 side, and the fourth charging plug terminal _TC4 is the other pole on the charger 15 side (FIG. 1 is a negative electrode) connection terminal. The charging plug 13 includes a third jumper wire _{J 3.}

When the charging plug 13 is connected to the battery pack 11, the first charging plug terminal T _C1 is connected to the first battery connection terminal _TB1 , and the second charging plug terminal T _C2 is the second battery connection terminal T. Connected to _B2 . The third charging plug terminal _TC3 is connected to the third battery connection terminal _TB3 , and the fourth charging plug terminal _TC4 is connected to the fourth battery connection terminal _TB4 .

Third jumper line _{J 3} is connected to the second charging plug terminal _{T C2} and a third charging plug terminal _{T C3.}
In the charge and discharge system 1 as described above, a discharge path to the first battery B ₁ and the second battery B ₂ from the load 14, from the charger 15 first battery B ₁ and the second to the battery B ₂ The charge path is switched using the discharge plug 12 and the charge plug 13.

Specifically, as shown in FIG. 1 (A), a discharge plug 12 when connected to the battery pack 11, the first battery B ₁ and the second battery B ₂ are connected in parallel. That is, one pole (the positive electrode in FIG. 1) of each of the first battery B ₁ and the second battery B ₂ is the first battery connection terminal T _B1 , the first discharge plug terminal T _DC1 , the first battery jumper wire _{J 1,} are connected to each other via the third discharge plug terminal _{T DC3,} and third battery connection terminal _{T B3.} In addition, the other electrode (the negative electrode in FIG. 1) of each of the first battery B ₁ and the second battery B ₂ is a second battery connection terminal T _B2 , a second discharge plug terminal T _DC2 , a second battery They are connected to each other via a jumper line J ₂ , a fourth discharge plug terminal T _DC4 , and a fourth battery connection terminal TB ₄ .

A discharge path, such as the following to the first battery B ₁ and the second battery B ₂ from the load 14 connected in parallel is formed. That is, one pole of the first battery B ₁ (positive electrode in FIG. 1) → first battery connection terminal T _B1 → first discharge plug terminal T _DC1 → first jumper line J ₁ → third discharge plug A charging path of terminal T _DC3 → third battery connection terminal T _B3 → load 14 → the other electrode of the first battery B ₁ (negative electrode in FIG. 1) is formed. The second one pole (in FIG. 1 positive) of the battery _{B 2} → load 14 → second battery connection terminal _{T B2} → second discharge plug terminal _{T DC2} → second jumper line _{J 2} → 4 Discharge plug terminal T _DC4 → the fourth battery connection terminal T _B4 → the other electrode (the negative electrode in FIG. 1) of the second battery B ₂ is formed.

On the other hand, as shown in FIG. 1 (B), the charge plug 13 when connected to the battery pack 11, the first battery B ₁ and the second battery B ₂ are connected in series. That is, the other electrode (the negative electrode in FIG. 1) of the first battery B _{1 and} the one electrode (the positive electrode in FIG. 1) of the second battery B ₂ are the second battery connection terminal T _B2 , the second electrode charging plug terminal _{T C2,} a third jumper wire _{J 3,} are connected to each other via the third charging plug terminal _{T C3,} and a third battery connection terminal _{T B3.}

Further, a second battery connection terminal _{T B2} having both a second load connection terminal _{T L2,} and the third battery connection terminal _{T B3} having both first load connection terminal _{T L1,} the second charging plug terminal T _C2, are connected to each other via a third jumper wire _{J 3,} and a third charging plug terminal _{T C3.} For this reason, the first load connection terminal T _L1 and the second load connection terminal T _L2 have the same potential.

Then, the following charging path is formed from the charger 15 to the first battery B ₁ and the second battery B ₂ connected in series. That is, a charging path is formed in which the charger 15 → the first charging plug terminal T _C1 → the first battery connection terminal T _B1 → the first electrode of the first battery B ₁ (the positive electrode in FIG. 1). Further, the other electrode of the first battery B ₁ (the negative electrode in FIG. 1) → the second battery connection terminal T _B2 → the second charging plug terminal T _C2 → the third jumper line J ₃ → the third charging plug charging path of the terminal T _C3 → third battery connection terminal T _B3 → second one pole of the battery B ₂ (in Figure 1 the cathode) is formed. Furthermore, a charging path of the other electrode of the second battery B ₂ (the negative electrode in FIG. 1) → the fourth battery connection terminal T _B4 → the fourth charging plug terminal T _C4 → the charger 15 is formed.

Thus, when the first battery B ₁ and the second battery B ₂ are discharged to the load 14, the discharge plug 12 is connected to the battery pack 11. As a result, the first battery B ₁ and the second battery B ₂ are connected in parallel, and the load 14 is connected to the first battery B ₁ and the second battery B ₂ connected in parallel. The connection relationship between the fourth battery connection terminals T _{B1 to} T _B4 and the first and second load connection terminals T _L1 and T _L2 is changed.

Since the first battery B ₁ and the second battery B ₂ are connected in parallel at the time of discharging, a desired voltage is applied to the load 14 for a long time compared to the case where a single battery is connected to the load 14. Can supply.

On the other hand, when the first battery B ₁ and the second battery B ₂ are charged, the charging plug 13 is connected to the battery pack 11. As a result, the first battery B ₁ and the second battery B ₂ are connected in series, and the first load connection terminal T _L1 and the second load connection terminal T _L2 have the same potential. The connection relationship between the fourth battery connection terminals T _{B1 to} T _B4 and the first and second load connection terminals T _L1 and T _L2 is changed.

Since the first load connection terminal T _L1 and the second load connection terminal T _L2 are at the same potential during charging, the first battery B ₁ and the second battery B ₂ are not discharged to the load 14 during charging. . Therefore, according to the charging / discharging system according to the embodiment, it is possible to prevent the load from being operated by the power supplied from the secondary battery during the charging of the secondary battery, and it is possible to ensure safety during charging.

In addition, since the first battery B ₁ and the second battery B ₂ are connected in series during charging, the current is smaller than when the first battery B ₁ and the second battery B ₂ are connected in parallel. by flowing into charge path, a first battery B ₁ and the second battery B ₂ can rapidly charge. Therefore, according to the charging / discharging system according to the embodiment, a plurality of secondary batteries can be rapidly charged without having a heat dissipation mechanism or a heat dissipation structure in the current path.

In addition, this invention is not limited to the above embodiment, A various improvement and change are possible within the range which does not deviate from the summary of this invention.
<Second configuration example>
For example, the charge / discharge system according to the embodiment may be configured as shown in FIG. FIG. 2 is a diagram illustrating a second configuration example of the charge / discharge system including the battery pack and the discharge plug according to the embodiment. As shown in FIG. 2, the charge / discharge system 2 includes a battery pack 21, a discharge plug 22, a charge plug 13, a load 14, and a charger 15. The battery pack 21 is mounted on an arbitrary device (not shown) together with the load 14.

As can be understood from the comparison with the first configuration example shown in FIG. 1, in the second configuration example shown in FIG. 2, the second battery connection terminal _TB2 and the first load connection terminal T _L1 are: The battery pack 21 is provided as separate terminals. The third battery connection terminal _TB3 and the second load connection terminal _TL2 are provided in the battery pack 21 as separate terminals.

Therefore, according to the difference from the first configuration example, the discharge plug 22 further includes a fifth discharge plug terminal T _DC5 and a sixth discharge plug terminal T _DC6 . When the discharge plug 12 is connected to the battery pack 11, the discharge plug terminal T _DC5 fifth is connected to the first load connection terminal T _L1, the discharge plug terminal T _DC6 sixth second load connection terminals T Connected to _L2 . The first jumper line _{J 1} is configured to connect the first discharge plug terminal _{T DC1} and the third discharge plug terminal _{T DC3} and the fifth discharge plug terminal _{T DC5.} The second jumper line _{J 2} is configured to connect the second discharge plug terminal _{T DC2} and fourth discharge plug terminal _{T DC4} and a sixth discharge plug terminal _{T DC6.}

In the charge and discharge system 2, and a discharge path to the first battery B ₁ and the second battery B ₂ from the load 14, the charging path from the charger 15 to the first battery B ₁ and the second battery B ₂ Are switched using the discharge plug 22 and the charge plug 13.

Specifically, as shown in FIG. 2 (A), the discharge plug 22 is connected to the battery pack 21, the first battery B ₁ and the second battery B _2, while referring to FIG. 1 above Connected in parallel. A discharge path, such as the following to the first battery B ₁ and the second battery B ₂ from the load 14 connected in parallel is formed. That is, one pole of the first battery B ₁ (positive electrode in FIG. 1) → first battery connection terminal T _B1 → first discharge plug terminal T _DC1 → first jumper line J ₁ → fifth discharge plug A charging path of terminal T _DC5 → first load connection terminal T _L1 → load 14 is formed. The load 14 → the second load connection terminal T _L2 → the sixth discharge plug terminal T _DC6 → the second jumper line J ₂ → the second discharge plug terminal T _DC2 → the second battery connection terminal T _B2 → the second A charging path called the other electrode (a negative electrode in FIG. 1) of one battery B ₁ is formed. In addition, one electrode of the second battery B ₂ (positive electrode in FIG. 1) → third battery connection terminal T _B3 → third discharge plug terminal T _DC3 → first jumper line J ₁ → fifth discharge plug A charging path of terminal T _DC5 → first load connection terminal T _L1 → load 14 is formed. Then, the load 14 → the second load connection terminal T _L2 → the sixth discharge plug terminal T _DC6 → the second jumper line J ₂ → the fourth discharge plug terminal T _DC4 → the fourth battery connection terminal T _B4 → the second A charging path called the other electrode (negative electrode in FIG. 1) of the _second battery B ₂ is formed.

On the other hand, as shown in FIG. 2 (B), when the charge plug 13 is connected to the battery pack 21, so that the first battery B ₁ and the second battery B ₂ is described above with reference to FIG. 1 Connected in series. Then, as described above with reference to FIG. 1, the charger 15, the first battery B ₁ and a second charging path to the battery B ₂ connected in series are formed.

Further, the first load connection terminal T _L1 and the second load connection terminal T _L2 are not connected to any terminal of the charging plug 13 and are opened. For this reason, the first load connection terminal T _L1 and the second load connection terminal T _L2 have the same potential.

As described above, also in the second configuration example shown in FIG. 2, when the first battery B ₁ and the second battery B ₂ are discharged to the load 14, the discharge plug 22 is connected to the battery pack 21. . As a result, the first battery B ₁ and the second battery B ₂ are connected in parallel, and the load 14 is connected to the first battery B ₁ and the second battery B ₂ connected in parallel. The connection relationship between the fourth battery connection terminals T _{B1 to} T _B4 and the first and second load connection terminals T _L1 and T _L2 is changed. On the other hand, when the first battery B ₁ and the second battery B ₂ are charged, the charging plug 13 is connected to the battery pack 21. As a result, the first battery B ₁ and the second battery B ₂ are connected in series, and the first load connection terminal T _L1 and the second load connection terminal T _L2 have the same potential. The connection relationship between the fourth battery connection terminals T _{B1 to} T _B4 and the first and second load connection terminals T _L1 and T _L2 is changed.

Therefore, even when the charge / discharge system according to the embodiment is configured as in the second configuration example illustrated in FIG. 2, the effects described above with respect to the first configuration example illustrated in FIG. 1 can be obtained.
<Third configuration example>
For example, the charge / discharge system according to the embodiment may be configured as shown in FIG. FIG. 3 is a diagram illustrating a third configuration example of the charge / discharge system including the battery pack and the discharge plug according to the embodiment. As shown in FIG. 3, the charge / discharge system 3 includes a battery pack 31, a discharge plug 32, a charge plug 13, a load 14, and a charger 15. The battery pack 31 is mounted on an arbitrary device (not shown) together with the load 14.

As can be understood from a comparison with the first configuration example shown in FIG. 1, in the third configuration example shown in FIG. 3, the second battery connection terminal _TB2 and the first load connection terminal T _L1 are: The battery pack 31 is provided as separate terminals. In the third configuration example shown in FIG. 3, the fourth battery connection terminal T _B4, combining the second load connection terminal T _L2, connected to the second battery B ₂ of the other electrode and the load 14 Has been.

Therefore, according to the difference from the first configuration example, the discharge plug 32 further includes a fifth discharge plug terminal _TDC5 . When the discharge plug 32 is connected to the battery pack 31, the discharge plug terminal T _DC5 fifth is connected to the first load connection terminal T _L1. The first jumper line _{J 1} is configured to connect the first discharge plug terminal _{T DC1} and the third discharge plug terminal _{T DC3} and the fifth discharge plug terminal _{T DC5.} Similarly to the configuration example shown in FIG. 1, a second jumper line J ₂ is configured to connect the second discharge plug terminal T _DC2 and the fourth discharge plug terminal T _DC4.

In the charge and discharge system 3, and a discharge path to the first battery B ₁ and the second battery B ₂ from the load 14, the charging path from the charger 15 to the first battery B ₁ and the second battery B ₂ Are switched using the discharge plug 32 and the charge plug 13.

Specifically, as shown in FIG. 3 (A), the discharge plug 32 is connected to the battery pack 31, the first battery B ₁ and the second battery B _2, while referring to FIG. 1 above Connected in parallel. A discharge path, such as the following to the first battery B ₁ and the second battery B ₂ from the load 14 connected in parallel is formed. That is, one pole of the first battery B ₁ (positive electrode in FIG. 1) → first battery connection terminal T _B1 → first discharge plug terminal T _DC1 → first jumper line J ₁ → fifth discharge plug A charging path of terminal T _DC5 → first load connection terminal T _L1 → load 14 is formed. Then, the load 14 → the fourth battery connection terminal T _B4 → the fourth discharge plug terminal T _DC4 → the second jumper line J ₂ → the second discharge plug terminal T _DC2 → the second battery connection terminal T _B2 → the second A charging path called the other electrode (a negative electrode in FIG. 1) of one battery B ₁ is formed. In addition, one electrode of the second battery B ₂ (positive electrode in FIG. 1) → third battery connection terminal T _B3 → third discharge plug terminal T _DC3 → first jumper line J ₁ → fifth discharge plug A charging path of terminal T _DC5 → first load connection terminal T _L1 → load 14 → the other electrode (the negative electrode in FIG. 1) of the second battery B ₂ is formed.

On the other hand, as shown in FIG. 3 (B), when the charge plug 13 is connected to the battery pack 31, so that the first battery B ₁ and the second battery B ₂ is described above with reference to FIG. 1 Connected in series. Then, as described above with reference to FIG. 1, the charger 15, the first battery B ₁ and a second charging path to the battery B ₂ connected in series are formed.

Further, the first load connection terminal _TL1 is not connected to any terminal of the charging plug 13 and is opened. For this reason, the first load connection terminal T _L1 and the second load connection terminal T _L2 have the same potential.

As described above, also in the third configuration example shown in FIG. 3, when the first battery B ₁ and the second battery B ₂ are discharged to the load 14, the discharge plug 32 is connected to the battery pack 31. . As a result, the first battery B ₁ and the second battery B ₂ are connected in parallel, and the load 14 is connected to the first battery B ₁ and the second battery B ₂ connected in parallel. The connection relationship between the fourth battery connection terminals T _{B1 to} T _B4 and the first and second load connection terminals T _L1 and T _L2 is changed. On the other hand, when the first battery B ₁ and the second battery B ₂ are charged, the charging plug 13 is connected to the battery pack 31. As a result, the first battery B ₁ and the second battery B ₂ are connected in series, and the first load connection terminal T _L1 and the second load connection terminal T _L2 have the same potential. The connection relationship between the fourth battery connection terminals T _{B1 to} T _B4 and the first and second load connection terminals T _L1 and T _L2 is changed.

Therefore, even when the charge / discharge system according to the embodiment is configured as in the third configuration example illustrated in FIG. 3, the effects described above with respect to the first configuration example illustrated in FIG. 1 can be obtained.
<Fourth configuration example>
For example, the charge / discharge system according to the embodiment may be configured as shown in FIG. FIG. 4 is a diagram illustrating a fourth configuration example of the charge / discharge system including the battery pack and the discharge plug according to the embodiment. As shown in FIG. 4, the charge / discharge system 4 includes a battery pack 41, a discharge plug 12, a charge plug 43, a load 14, and a charger 15. The battery pack 41 is mounted on an arbitrary device (not shown) together with the load 14.

In the fourth configuration example shown in FIG. 4, the battery pack 41 includes, in addition to the same components as the battery pack 11 (FIG. 1), a series / parallel changeover switch S _SP , a control unit CON, and a first detection terminal T _D1. And a second detection terminal _TD2 . The charging plug 43 does not include the second charging plug terminal T _C2 and the third charging plug terminal T _C3 included in the charging plug 13 (FIG. 1), and the first charging plug side detection terminal T _CD1 , 2 charging plug side detection terminals T _CD2 and a fourth jumper line J ₄ are further included.

Serial-parallel switching switch S _SP is a switch for switching the connection first battery B ₁ and the second battery B ₂ in series or in parallel. One end of the series-parallel changeover switch S _SP is connected to the first battery B ₁ of the other pole (in FIG. 4 negative), the serial-parallel switching switch S _SP other end, one of the second battery B ₂ It is connected to the pole (positive electrode in FIG. 4).

The control unit CON is configured by, for example, a CPU (Central Processing Unit), a multi-core CPU, or a programmable device (FPGA (Field Programmable Gate Array), PLD (Programmable Logic Device), or the like). The control unit CON controls the operation of the battery pack 41 as a whole. In the fourth configuration example, the control unit CON, the detection signal transmitted to the first detecting terminal T _D1 monitors whether or not there is an input from the second detecting terminal T _D2. The detection signal includes a current. In that case, the control unit CON is applied a voltage to the first detecting terminal T _D1, whether current flows in the second detecting terminal T _D2 monitors, when current flows through the second detecting terminal T _D2 , It is determined that the detection signal is input from the second detection terminal _TD2 . The control unit CON, according to the monitoring result, controls the opening and closing of the series-parallel changeover switch _{S SP.}

Specifically, as shown in FIG. 4A, when the battery pack 41 is connected to the discharge plug 12, the detection signal transmitted from the control unit CON to the first detection terminal _TD1 is the second not input to the control unit CON of the detecting terminal _{T D2.} Therefore, the control unit CON performs control so that the series / parallel changeover switch _SSP is opened. Thus, when the first battery B ₁ and the second battery B ₂ is discharged to the load 14, the serial-parallel switching switch S _SP is opened. When the battery pack 41 is connected to the discharge plug 12 and the series-parallel changeover switch _SSP is opened, as described above with reference to FIG. 1A, the first battery B ₁ and the second battery B ₂ are connected in parallel.

On the other hand, as shown in FIG. 4B, when the battery pack 41 is connected to the charging plug 43, the detection signal transmitted from the control unit CON to the first detection terminal _TD1 is transmitted through the following path. Input from the second detection terminal _TD2 to the control unit CON. That is, the control unit CON → first detection terminal T _D1 → first charging plug side detection terminal T _CD1 → fourth jumper line J ₄ → second charging plug side detection terminal T _CD2 → second detection terminal T _The detection signal is input to the control unit CON through the path _D2 . Therefore, the control unit CON controls the series / parallel changeover switch _{SSP to} be closed. Thus, when the first battery B ₁ and the second battery B ₂ is charged, a series-parallel changeover switch S _SP is closed. When the battery pack 41 is connected to charging plug 43, closing the serial-parallel switching switch S _SP, the first battery B ₁ and the second battery B ₂ are connected in series, the charging path such as: It is formed. That is, a charging path is formed in which the charger 15 → the first charging plug terminal T _C1 → the first battery connection terminal T _B1 → the first electrode of the first battery B ₁ (the positive electrode in FIG. 4). In addition, a charging path is formed in which the other electrode of the first battery B ₁ (the negative electrode in FIG. 4) → the series-parallel changeover switch S _SP → the one electrode of the second battery B ₂ (the positive electrode in FIG. 4). Further, a charging path of the other electrode of the second battery B ₂ (the negative electrode in FIG. 4) → the fourth battery connection terminal T _B4 → the fourth charging plug terminal T _C4 → the charger 15 is formed. Since the second battery connection terminal _TB2 and the third battery connection terminal _TB2 are open, the first load connection terminal _TL1 and the second load connection terminal _TL2 have the same potential.

Therefore, even when the charge / discharge system according to the embodiment is configured as in the fourth configuration example illustrated in FIG. 4, the effects described above with respect to the first configuration example illustrated in FIG. 1 can be obtained.
Further, the charging plug 43 does not include the second charging plug terminal T _C2 and the third charging plug terminal T _C3 in order to switch the connection of the first battery B ₁ and the second battery B ₂ in series. Also good. Therefore, when the charge / discharge system according to the embodiment is configured as in the fourth configuration example shown in FIG. 4, a plurality of secondary batteries connected in parallel are connected in series using the existing charge plug. Can be switched.

Further, when a detection signal transmitted from the control unit CON is not input to the control unit CON may open the serial-parallel switching switch S _SP, the first battery B ₁ and the second battery B ₂ are connected in parallel. Therefore, the first battery B ₁ and the second battery B ₂ is compared with the case which are connected in series, the voltage of the first battery connection terminal T _B1 and the fourth battery connection terminal T _B4 to the low-voltage Become. Therefore, according to the fourth configuration example, even when the charging plug 43 and the discharging plug 12 are not connected and the first battery connecting terminal _TB1 and the fourth battery connecting terminal _TB4 are exposed, Safety can be secured.

The series / parallel changeover switch _SSP is on the charging path. Therefore, for example, when an abnormality such as overvoltage or overcurrent occurs during charging by the charger 15, the control unit CON controls the serial parallel switching switch _SSP to open the charging path, The failure of the _first battery B ₁ and the second battery B ₂ can be prevented. On the other hand, the series / parallel changeover switch _SSP is not on the discharge path. Therefore, at the time of discharge to the first battery B ₁ and the second battery B ₂ from the load 14, nor requiring power to close the series-parallel changeover switch S _SP.

The fourth configuration example can be combined not only with the first configuration example as described above with reference to FIG. 4 but also with the second configuration example or the third configuration example.
<Fifth configuration example>
For example, the charge / discharge system according to the embodiment may be configured as shown in FIG. FIG. 5 is a diagram illustrating a fifth configuration example of the charge / discharge system including the battery pack and the discharge plug according to the embodiment. As shown in FIG. 5, the charge / discharge system 5 includes a battery pack 51, a discharge plug 52, a charge plug 13, a load 14, and a charger 15. The battery pack 51 is mounted on an arbitrary device (not shown) together with the load 14.

In the fifth configuration example shown in FIG. 5, the battery pack 51 includes a first switch S ₁ , a second switch S ₂ , a control unit CON, in addition to the same components as the battery pack 11 (FIG. 1). A third detection terminal T _D3 and a fourth detection terminal T _D4 are included. In addition to the same components as the discharge plug 12 (FIG. 1), the discharge plug 52 includes a first discharge plug side detection terminal T _DD1 , a second discharge plug side detection terminal T _DD2 , and a fifth jumper. including a line _{J 5.}

The first switch S ₁ and the second switch S ₂ are connected to each terminal of the battery pack 51 due to the reflux current generated from the potential difference between the first battery B ₁ and the second battery B ₂ connected in parallel. It is provided to prevent an arc from flying between each terminal of the discharge plug 52. Figure In the example shown in 5, the first switch S ₁ is provided on the power line between the first one pole of battery B ₁ and the first battery connection terminal T _B1, the second switch S ₂ Is provided on the power line between the other pole of the _second battery B2 and the fourth battery connection terminal _TB4 . The first switch S _1, the switch S ₂ well, the second be provided to a power line between the first other pole and a second battery connection terminal T _B2 of the battery B ₁ represents, first You may provide in the electric power line between one pole of _2nd battery B2, and 3rd battery connection terminal _TB3 .

As is clear from the reference numerals, the third detection terminal T _D3 and the fourth detection terminal T _D4 can be provided separately from the first detection terminal T _D1 and the second detection terminal T _D2 (FIG. 4). It is. FIG. 6 is an explanatory diagram of the connection order of the terminals of the battery pack and the discharge plug in the fifth configuration example. In the example shown in FIG. 6, the positions at which the first to fourth battery connection terminals T _{B1 to} T _B4 are respectively connected to the corresponding first to fourth discharge plug terminals T _{DC1 to} T _DC4 , and the third detection The positions of the terminal T _D3 and the fourth detection terminal T _D4 are different from the corresponding positions of the corresponding first discharge plug side detection terminal T _DD1 and second discharge plug side detection terminal T _DD2 .

When the discharge plug 52 is connected to the battery pack 51 as shown in FIG. 5A, each terminal of the battery pack 51 is connected in the order of (A) → (B) → (C) shown in FIG. 52 to be connected to each terminal. That is, first, the first to fourth battery connection terminals T _{B1 to} T _B4 are respectively connected to the corresponding first to fourth discharge plug terminals T _{DC1 to} T _DC4 (FIG. 6B). Thereafter, the third detection terminal T _D3 and the fourth detection terminal T _D4 are respectively connected to the corresponding first discharge plug side detection terminal T _DD1 and second discharge plug side detection terminal T _DD2 (FIG. 6). (C)).

On the other hand, when the discharge plug 52 is removed from the battery pack 51, the terminals of the battery pack 51 are connected to the terminals of the corresponding discharge plug 52 in the order of (C) → (B) → (A) shown in FIG. Each is configured to be removed. That is, first, the third detection terminal T _D3 and the fourth detection terminal T _D4 are respectively disconnected from the corresponding first discharge plug side detection terminal T _DD1 and second discharge plug side detection terminal T _DD2 ( FIG. 6 (B)). Thereafter, the first to fourth battery connection terminals T _{B1 to} T _B4 are removed from the corresponding first to fourth discharge plug terminals T _{DC1 to} T _DC4 (FIG. _6A ).

In the fifth configuration example, the control unit CON, the detection signal transmitted to the third detection terminal T _D3 monitors whether or not there is an input from the fourth detection terminal T _D4. The detection signal includes a current. In that case, the control unit CON is applied a voltage to the third detection terminal T _D3, monitors whether current flows in the fourth detection terminal T _D4, When current flows through the fourth detection terminal T _D4 , It is determined that the detection signal is input from the fourth detection terminal _TD4 . The control unit CON, according to the monitoring result, controls the first on-off switch _{S 1} and the second switch _{S 2.}

Specifically, when the battery pack 41 is connected to the discharge plug 12, first, the first to fourth battery connection terminals T _{B1 to} T _B4 are changed to the first to fourth discharge plug terminals T _{DC1 to} T _DC4 . Connected. Then, a third detection terminal _{T D3} and a fourth detection terminal _{T D4} is connected to the first discharge plug detection terminal _{T DD1} and second discharge plug side detecting terminal _{T DD2.} As a result, the detection signal transmitted from the control unit CON to third detection terminal T _D3 is input from the fourth detection terminal T _D4 through a path such as the following to the control unit CON. That is, the control unit CON → the third detection terminal T _D3 → the first discharge plug side detection terminal T _DD1 → the fifth jumper line J ₅ → the second discharge plug side detection terminal T _DD2 → the fourth detection terminal T _The detection signal is input to the control unit CON through the route _D4 . Therefore, the control unit CON controls such that the first switch _{S 1} and the second switch _{S 2} is closed. As a result, similarly to the first configuration example shown in FIG. 1 (A), discharge path first battery B ₁ and the second battery B ₂ are connected in parallel is formed.

Thus, the first switch _{S 1} and the second switch S after the first to connect the fourth battery terminal _T B1 _{through T B4} is connected to the first to fourth discharge plug terminal _T DC1 _{through T DC4 2} is closed, and a discharge path is formed in which the first battery B ₁ and the second battery B ₂ are connected in parallel. Therefore, even if there is a potential difference between the first battery B ₁ and the second battery B ₂ , the first to fourth battery connection terminals T _{B1 to} T _B4 are connected to the first to fourth discharge plug terminals T _{DC1 to} T _{DC. Since the} reflux current does not flow when connected to the _{DC 4} , it is possible to prevent an arc from flying between each terminal of the battery pack 51 and each terminal of the discharge plug 52. Moreover, the surface of each terminal is made uneven by the arc, and it is possible to prevent the fitting between the terminals from deteriorating.

On the other hand, when the discharge plug 52 is removed from the battery pack 51, first, the third detection terminal T _D3 and the fourth detection terminal T _D4 are the first discharge plug side detection terminal T _DD1 and the second discharge plug side. _Disconnected from the detection terminal _TDD2 . As a result, the detection signal transmitted from the control unit CON to third detection terminal _{T D3} does not input to the control unit CON from the fourth detection terminal _{T D4.} Therefore, the control unit CON has a first switch _{S 1} and the second switch _{S 2} is controlled to open. When the first switch S ₁ and the second switch S ₂ is opened, the aforementioned discharge path has been formed is cut. Thereafter, the first to fourth battery connection terminals T _{B1 to} T _B4 are disconnected from the first to fourth discharge plug terminals T _{DC1 to} T _DC4 .

Thus, the first switch _{S 1} and the second switch before the battery connection terminal _T B1 _{through T B4} of the first to fourth is removed from the first to fourth discharge plug terminal _T DC1 _{through T DC4} S ₂ is open and discharge path first battery B ₁ and the second battery B ₂ are connected in parallel is disconnected. Therefore, even if there is a potential difference between the first battery B ₁ and the second battery B ₂ , the first to fourth battery connection terminals T _{B1 to} T _B4 are connected to the first to fourth discharge plug terminals T _{DC1 to} T _{DC. Since the} return current does not flow when removed from the _{DC 4,} it is possible to prevent an arc from flying between each terminal of the battery pack 51 and each terminal of the discharge plug 52. Moreover, the surface of each terminal is made uneven by the arc, and it is possible to prevent the fitting between the terminals from deteriorating.

The charging plug 13 as shown in FIG. 5 (B) when it is connected to the battery pack 51, the control unit CON controls such that the first switch S ₁ and the second switch S ₂ is closed . As a result, and FIG. 1 (B) first battery B ₁ and the second battery B ₂ as in the first configuration example shown in are connected in series, similar to the configuration example shown in FIG. 1 (B) A charging path is formed. Note that the connection detection between the charging plug 13 and the battery pack 51 may be realized by, for example, a configuration using a connection detection signal as shown in FIG.

Therefore, even when the charge / discharge system according to the embodiment is configured as in the fifth configuration example illustrated in FIG. 5, the effects described above with respect to the first configuration example illustrated in FIG. 1 can be obtained.
Note that the fifth configuration example can be combined not only with the first configuration example as described above with reference to FIG. 5 but also with any one of the second to fourth configuration examples.
<Sixth configuration example>
As described above in the first configuration example, each of the first battery B ₁ and the second battery B ₂ is one or more secondary battery cells such as a lithium ion battery or a lead storage battery. When each of the first battery B ₁ and the second battery B ₂ includes a plurality of battery cells, the battery pack according to the embodiment may be configured as shown in FIG. 7, for example. FIG. 7 is a diagram illustrating a sixth configuration example of the charge / discharge system including the battery pack and the discharge plug according to the embodiment. As shown in FIG. 7, the charge / discharge system 6 includes a battery pack 61, a discharge plug 12, a charge plug 13, a load 14, and a charger 15. The battery pack 61 is mounted on an arbitrary device (not shown) together with the load 14.

In the example shown in FIG. 7, the first battery B ₁ and the second battery B _2, the two sets of two battery cells B _C connected in series are respectively connected in parallel. The present invention is not limited to the example shown in FIG. 7, the number of battery cells B _C in series and / or parallel connections may be arbitrary. In addition, when the number of parallel connections increases, a switch that can cut off the increased current path may be arbitrarily added.

  Even when the charge / discharge system according to the embodiment is configured as in the sixth configuration example illustrated in FIG. 5, the effects described above with respect to the first configuration example illustrated in FIG. 1 can be obtained. Moreover, when the charge / discharge system according to the embodiment is configured as in the sixth configuration example shown in FIG. 5, a battery pack having a capacity corresponding to the power consumption of the load can be realized.

Note that the sixth configuration example can be combined not only with the first configuration example as described above with reference to FIG. 7 but also with any one of the second to fifth configuration examples.
<Seventh configuration example>
In the configuration example shown in FIG. 1 to FIG. 7, two secondary batteries (first battery B ₁ and second battery B ₂ ) whose connection relationship is changed in parallel or in series are included in the battery pack. The battery pack may include three or more secondary batteries whose connection relation is changed in parallel or in series. The number of battery connection terminals and load connection terminals included in the battery pack may be changed according to the number of secondary batteries whose connection relationship is changed in parallel or in series. Further, the number of discharge plug terminals included in the discharge plug, the number of jumper wires, and the configuration may be changed according to the number of secondary batteries whose connection relationship is changed in parallel or in series.

  FIG. 8 is a diagram illustrating a sixth configuration example of the charge / discharge system including the battery pack and the discharge plug according to the embodiment. In the example shown in FIG. 8, the battery pack according to the embodiment includes three secondary batteries. As shown in FIG. 8, the charge / discharge system 7 includes a battery pack 71, a discharge plug 72, a charge plug 73, a load 14, and a charger 15. The battery pack 71 is mounted on an arbitrary device (not shown) together with the load 14.

The battery pack 71 includes a third battery B ₃ , a fifth battery connection terminal T _B5 , and a sixth battery connection terminal T _B6 in addition to the same components as the battery pack 11 (FIG. 1). Battery connection terminal T _B5 The fifth (8, positive terminal) third one pole of the battery B ₃ are connected to. Battery connection terminal T _B6 sixth, (8, negative terminal) third battery B ₃ of the other electrode is connected to.

The discharge plug 72 includes a seventh discharge plug terminal _TDC7 and an eighth discharge plug terminal _TDC8 in addition to the same components as the discharge plug 12 (FIG. 1). When the discharge plug 72 is connected to the battery pack 71, the discharge plug terminal T _DC7 seventh is connected to the battery connection terminal T _B5 of the fifth, the discharge plug terminal T _DC8 the eighth battery connection terminal T of the 6 Connected to _B6 . First jumper line _{J 1} is connected to the first discharge plug terminal _{T DC1} and the third discharge plug terminal _{T DC3} and seventh discharge plug terminal _{T DC7.} The second jumper line _{J 2} is connected to the second discharge plug terminal _{T DC2} and fourth discharge plug terminal _{T DC4} and eighth discharge plug terminal _{T DC8.}

The charging plug 73 includes a fifth charging plug terminal T _C5 , a sixth charging plug terminal T _C6 , and a sixth jumper line J ₆ in addition to the same components as the charging plug 13 (FIG. 1). In the charging plug 73, the connection terminal of the other pole (negative electrode in FIG. 8) on the charger 15 side is the sixth charging plug terminal _TC6 . Sixth jumper wire _{J 6} of is connected to the fourth charging plug terminal _{T C4} and the fifth charge plug terminal _{T C5} of. When the charging plug 73 is connected to the battery pack 71, the fifth charging plug terminal _TC5 is connected to the fifth battery connecting terminal _TB5 , and the sixth charging plug terminal _TC6 is connected to the sixth battery connecting terminal T. Connected to _B6 .

In the charging / discharging system 7 as described above, the discharging path from the _first to third batteries B _{1 to} B ₃ to the load 14 and the charging from the charger 15 to the first to third batteries B _{1 to} B ₃ are performed. The path is switched using the discharge plug 72 and the charge plug 73.

Specifically, as shown in FIG. 8A, when the discharge plug 72 is connected to the battery pack 71, the first to third batteries B _{1 to} B ₃ are connected in parallel. That is, one of the first to third batteries B _{1 to} B ₃ (the positive electrode in FIG. 8) is connected to the first, third, and fifth battery connection terminals T _B1 , T _B3 , and T _B5 . , First, third, and seventh discharge plug terminals T _DC1 , T _DC3 , T _DC7 and the first jumper line J ₁ are connected to each other. The other poles (negative electrodes in FIG. 8) of the first to third batteries B _{1 to} B ₃ are the second, fourth, and sixth battery connection terminals T _B2 , T _B4 , and T _B6 . , Second, fourth, and eighth discharge plug terminals T _DC2 , T _DC4 , T _DC8 and the second jumper line J ₂ are connected to each other.

And the following discharge path | route from the _{1st- 3rd} battery B1-B3 connected in parallel to the load 14 is formed. That is, one pole of the first battery B ₁ (positive electrode in FIG. 8) → first battery connection terminal T _B1 → first discharge plug terminal T _DC1 → first jumper line J ₁ → third discharge plug A charging path of terminal T _DC3 → third battery connection terminal T _B3 → load 14 → the other electrode of the first battery B ₁ (negative electrode in FIG. 8) is formed. The second one pole (positive electrode in Fig. 8) of the battery _{B 2} → load 14 → second battery connection terminal _{T B2} → second discharge plug terminal _{T DC2} → second jumper line _{J 2} → 4 Discharge plug terminal T _DC4 → the fourth battery connection terminal T _B4 → the other electrode of the second battery B ₂ (a negative electrode in FIG. 8) is formed. Furthermore, one pole of the third battery B ₃ (the positive electrode in FIG. 8) → the fifth battery connection terminal T _B5 → the seventh discharge plug terminal T _DC7 → the first jumper line J ₁ → the third discharge plug Terminal T _DC3 → Third battery connection terminal T _B3 → Load 14 →→ Second battery connection terminal T _B2 → Second discharge plug terminal T _DC2 → Second jumper wire J ₂ → Eighth discharge plug terminal T _DC8 → charging path is formed that sixth battery connection terminal T _B6 → third battery B ₃ of the other pole of (in FIG. 8 negative).

On the other hand, as shown in FIG. 8B, when the charging plug 73 is connected to the battery pack 71, the first to third batteries B _{1 to} B ₃ are connected in series. That is, the first battery B ₁ of the other pole (8 negative) and the second one pole of the battery B ₂ (8 positive), a second battery connection terminal T _B2, the second charging plug terminal _{T C2,} a third jumper wire _{J 3,} I am connected to each other via the third charging plug terminal _{T C3,} and a third battery connection terminal _{T B3.} The other electrode of the second battery B ₂ (the negative electrode in FIG. 8) and the one electrode of the third battery B ₃ (the positive electrode in FIG. 8) are the fourth battery connection terminal T _B4 , the fourth electrode charging plug terminal _{T C4,} the sixth jumper wire _{J 6} of and connected to each other via a fifth charging plug terminal _{T C5,} and a fifth battery connection terminals _{T B5} of.

Further, a second battery connection terminal _{T B2} having both a second load connection terminal _{T L2,} and the third battery connection terminal _{T B3} having both first load connection terminal _{T L1,} the second charging plug terminal T _C2, are connected to each other via a third jumper wire _{J 3,} and a third charging plug terminal _{T C3.} For this reason, the first load connection terminal T _L1 and the second load connection terminal T _L2 have the same potential.

Then, the following charging path is formed from the charger 15 to the first to third batteries B _{1 to} B ₃ connected in series. That is, a charging path of the charger 15 → the first charging plug terminal T _C1 → the first battery connection terminal T _B1 → the first electrode of the first battery B ₁ (the positive electrode in FIG. 8) is formed. Further, the other electrode of the first battery B ₁ (the negative electrode in FIG. 8) → the second battery connection terminal T _B2 → the second charging plug terminal T _C2 → the third jumper line J ₃ → the third charging plug charging path of the terminal T _C3 → third battery connection terminal T _B3 → second one pole of the battery B ₂ (in FIG. 8 positive electrode) is formed. Further, the other electrode of the second battery B ₂ (the negative electrode in FIG. 8) → the fourth battery connection terminal T _B4 → the fourth charging plug terminal T _C4 → the sixth jumper line J ₆ → the fifth charging plug A charging path of terminal T _C5 → fifth battery connection terminal T _B5 → one electrode of the third battery B ₃ (positive electrode in FIG. 8) is formed. In addition, a charging path of the other electrode of the third battery B ₃ (the negative electrode in FIG. 8) → the sixth battery connection terminal T _B6 → the sixth charging plug terminal T _C6 → the charger 15 is formed.

As described above, when the first to third batteries B _{1 to} B ₃ are discharged to the load 14, the discharge plug 72 is connected to the battery pack 71. As a result, the first to third batteries B _{1 to} B ₃ are connected in parallel, and the load 14 is connected to the _first to third batteries B _{1 to} B ₃ connected in parallel. 6 battery connection terminals T _{B1 to} T _B6 and the connection relations of the first and second load connection terminals T _L1 and T _L2 are changed.

On the other hand, when the first to third batteries B _{1 to} B ₃ are charged, the charging plug 73 is connected to the battery pack 71. As a result, the first to third batteries B _{1 to} B ₃ are connected in series, and the first load connection terminal T _L1 and the second load connection terminal T _L2 have the same potential. 6 battery connection terminals T _{B1 to} T _B6 and the connection relations of the first and second load connection terminals T _L1 and T _L2 are changed.

  Therefore, even when the battery pack includes three or more secondary batteries whose connection relationship is changed in parallel or in series as in the seventh configuration example, the configuration examples shown in FIGS. The same effects as those obtained from the above can be obtained.

1, 2, 3, 4, 5, 6, 7 Charge / Discharge System 11, 21, 31, 41, 51, 61, 71 Battery Pack 12, 22, 32, 52, 72 Discharge Plug 13, 43, 73 Charge Plug 14 Load 15 Charger B ₁ 1st battery B ₂ 2nd battery B ₃ 3rd battery B _C battery cell CON Control part J ₁ 1st jumper line J ₂ 2nd jumper line J ₃ 3rd jumper line J ₄ 4th jumper line J ₅ 5th jumper line J ₆ 6th jumper line T _B1 1st battery connection terminal T _B2 2nd battery connection terminal T _B3 3rd battery connection terminal T _B4 4th Battery connection terminal T _B5 Fifth battery connection terminal T _B6 Sixth battery connection terminal T _C1 First charging plug terminal T _C2 Second charging plug terminal T _C3 Third charging plug terminal T _C4 Fourth charging plug terminal _{T C5} fifth of charging plug terminal _{T C6} sixth of charge Plug terminal _{T D1} first detection terminal _{T D2} second sense terminal _{T D3} third detection terminal _{T D4} fourth detection terminal _{T CD1} first charging plug-side detection terminal _{T CD2} second charging plug-side detecting terminal T _DC1 first discharge plug terminal T _DC2 second discharge plug terminal T _DC3 third discharge plug terminal T _DC4 fourth discharge plug terminal T _DC5 fifth discharge plug terminal T _DC6 sixth discharge plug terminal T _DC7 7th discharge plug terminal T _DC8 8th discharge plug terminal T _DD1 1st discharge plug side detection terminal T _DD2 2nd discharge plug side detection terminal T _L1 1st load connection terminal T _L2 2nd load connection terminal S ₁ first switch S ₂ second switch S _SP series / parallel switch

Claims (11)

A first battery and a second battery;
A first battery connection terminal connected to one pole of the first battery;
A second battery connection terminal connected to the other electrode of the first battery;
A third battery connection terminal connected to one pole of the second battery;
A fourth battery connection terminal connected to the other electrode of the second battery;
A first load connection terminal on one pole and a second load connection terminal on the other pole connected to a load;
When the first battery and the second battery are discharged to the load, the first battery and the second battery are connected in parallel, and the first battery and the second battery connected in parallel are connected. The connection relationship between the first to fourth battery connection terminals and the first and second load connection terminals is changed so that the load is connected to the battery.
When the first battery and the second battery are charged, the first battery and the second battery are connected in series, and the first load connection terminal and the second load connection terminal A battery pack in which the connection relationship between the first to fourth battery connection terminals and the first and second load connection terminals is changed so that the two have the same potential. The battery pack according to claim 1,
The second battery connection terminal also serves as the second load connection terminal, and is connected to the other electrode of the first battery and the load.
The third battery connection terminal also serves as the first load connection terminal, and is connected to the one electrode of the second battery and the load;
When the first battery and the second battery are discharged to the load, the first battery connection terminal and the third battery connection terminal are connected, and the second battery connection terminal and the A fourth battery connection terminal is connected,
When the first battery and the second battery are charged, the first battery connection terminal is connected to a connection terminal of one pole on the charger side, and the fourth battery connection terminal is A battery pack connected to the connection terminal of the other pole on the charger side, wherein the second battery connection terminal and the third battery connection terminal are connected. The battery pack according to claim 1,
When the first battery and the second battery are discharged to the load, the first battery connection terminal, the third battery connection terminal, and the first load connection terminal are connected, and A second battery connection terminal, the fourth battery connection terminal, and the second load connection terminal are connected;
When the first battery and the second battery are charged, the first battery connection terminal is connected to a connection terminal of one pole on the charger side, and the fourth battery connection terminal is The second battery connection terminal and the third battery connection terminal are connected to the other electrode connection terminal on the charger side, and the first load connection terminal and the second load connection terminal are Battery pack to be opened. The battery pack according to claim 1,
The fourth battery connection terminal also serves as the second load connection terminal, and is connected to the other electrode of the second battery and the load.
When the first battery and the second battery are discharged to the load, the first battery connection terminal, the third battery connection terminal, and the first load connection terminal are connected, and A second battery connection terminal and the fourth battery connection terminal are connected;
When the first battery and the second battery are charged, the first battery connection terminal is connected to a connection terminal of one pole on the charger side, and the fourth battery connection terminal is A battery pack that is connected to a connection terminal of the other pole on the charger side, wherein the second battery connection terminal and the third battery connection terminal are connected, and the first load connection terminal is opened. The battery pack according to any one of claims 1 to 4,
A serial-parallel changeover switch having one end connected to the other electrode of the first battery and the other electrode connected to the one electrode of the second battery;
When the first battery and the second battery are discharged to the load, the series / parallel switch is opened,
When the first battery and the second battery are charged, the battery pack is closed. The battery pack according to any one of claims 1 to 4,
A serial-parallel changeover switch having one end connected to the other electrode of the first battery and the other electrode connected to the one electrode of the second battery;
Connection between the battery pack and a charging plug including a charging plug terminal of one pole connected to the first battery connecting terminal and a charging plug terminal of the other pole connected to the fourth battery connecting terminal Is detected, the series-parallel switch is closed,
The battery pack is opened when the connection between the charging plug and the battery pack is not detected. The battery pack according to any one of claims 1 to 6,
Provided on a power line between the one electrode of the first battery and the first battery connection terminal, or on a power line between the other electrode of the first battery and the second battery connection terminal. A first switch configured;
Provided on a power line between the one electrode of the second battery and the third battery connection terminal, or on a power line between the other electrode of the second battery and the fourth battery connection terminal And a second switch provided,
A connection between the first battery connection terminal and the third battery connection terminal is detected, and a connection between the discharge plug and the battery pack connecting the second battery connection terminal and the fourth battery connection terminal is detected. The first switch and the second switch are closed,
When the connection between the discharge plug and the battery pack is no longer detected, the first switch and the second switch are opened. The battery pack according to any one of claims 1 to 7,
The first battery and the second battery are battery packs each including a plurality of battery cells connected in series and / or in parallel. A discharge plug connected to the battery pack according to claim 2,
A first discharge plug terminal connected to the first battery connection terminal;
A second discharge plug terminal connected to the second battery connection terminal;
A third discharge plug terminal connected to the third battery connection terminal;
A fourth discharge plug terminal connected to the fourth battery connection terminal;
A first jumper line connecting the first discharge plug terminal and the third discharge plug terminal;
A discharge plug including a second jumper line connecting the second discharge plug terminal and the fourth discharge plug terminal. A discharge plug connected to the battery pack according to claim 3,
A first discharge plug terminal connected to the first battery connection terminal;
A second discharge plug terminal connected to the second battery connection terminal;
A third discharge plug terminal connected to the third battery connection terminal;
A fourth discharge plug terminal connected to the fourth battery connection terminal;
A fifth discharge plug terminal connected to the first load connection terminal;
A sixth discharge plug terminal connected to the second load connection terminal;
A first jumper line connecting the first discharge plug terminal, the third discharge plug terminal, and the fifth discharge plug terminal;
A discharge plug including a second jumper line connecting the second discharge plug terminal, the fourth discharge plug terminal, and the sixth discharge plug terminal. A discharge plug connected to the battery pack according to claim 4,
A first discharge plug terminal connected to the first battery connection terminal;
A second discharge plug terminal connected to the second battery connection terminal;
A third discharge plug terminal connected to the third battery connection terminal;
A fourth discharge plug terminal connected to the fourth battery connection terminal;
A fifth discharge plug terminal connected to the first load connection terminal;
A first jumper line connecting the first discharge plug terminal, the third discharge plug terminal, and the fifth discharge plug terminal;
A discharge plug including a second jumper line connecting the second discharge plug terminal and the fourth discharge plug terminal.

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