JP4126167B2 - Charge / discharge circuit for series connected battery group - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a charge / discharge circuit for a battery group connected in series, and in particular, used for a backup power source in a factory or a hospital, used for a load leveling device for storing nighttime power and releasing it in the daytime, or mounted on an electric vehicle. Applied to lithium secondary battery.
[0002]
[Prior art]
FIG. 14 shows a battery group in which a large number of batteries are connected in series.
Hereinafter, a case where each of the batteries is a lithium battery will be described as an example.
[0003]
Currently, some lithium batteries under development have a single-cell electromotive force of about 4V. This lithium battery is often used by being connected in series. For example, 4 to 40 lithium batteries may be connected in series.
[0004]
When lithium batteries are used connected in series, a difference in characteristics of each lithium battery becomes a problem. That is, when charging and discharging are repeated, the battery voltage varies due to the difference in the characteristics of the batteries. When the charging / discharging operation is repeated, even if the charging / discharging operation time is the same, a difference appears in the charging voltage or discharging voltage of each battery. In the case of a lithium battery, if it is overcharged, it may lead to an accident, and if it is overdischarged, the capacity of the battery will be lost. For these reasons, strict protection and management are required for overcharge and overdischarge.
[0005]
If the battery voltage of a lithium battery connected in series on a single line varies, the charging must be terminated in accordance with the battery that has reached the charge end voltage first, so the other batteries are completely In other words, the other batteries cannot be completely discharged because it is necessary to terminate the discharge in accordance with the battery that reaches the discharge end voltage first. For this reason, sufficient charge and discharge as a whole battery group connected in series cannot be performed.
[0006]
As a technique for suppressing this variation, there is an example in which a Zener diode as shown in FIG. 15 is used (see Japanese Patent Laid-Open No. 11-332115). In the technology described in this publication, an emphasis is placed on preventing the charging voltage from becoming excessive.
However, Zener diodes are not suitable for large currents. The Zener diode is used at about 1 to 3 A, and cannot be used at a level exceeding 4 A.
[0007]
Lithium batteries connected in series are used, for example, for power load leveling for storing nighttime power and releasing it during the daytime. In this type of application, it is assumed that a current of 10 to 20 A can be handled. Therefore, Zener diodes (general-purpose products) are not suitable for the above applications.
[0008]
Therefore, as shown in FIG. 16, a circuit for bypassing the current has been studied. Regarding the battery B1, the switch S111 is turned on and the switch S112 is turned off during normal operation, and the switch S111 is turned off and the switch S112 is turned on during bypass.
[0009]
According to this circuit configuration, if the capacitance of the switches S111, S112,... S1n1, S1n2 is increased, it can be applied to a large current. However, when the switches are switched, for example, when the battery B1 is bypassed, it is necessary to provide a period in which both the switches S111 and S112 are OFF, such as turning off the switch S111 and then turning on the switch S112 ( When both switches S111 and S112 are ON, the battery B1 is short-circuited).
[0010]
However, during the period when both the switches S111 and S112 are OFF, since there is no route for current to flow, an excessive surge voltage is generated at the switch S111 from the moment when the switch S111 that has been ON is switched OFF. There was a fear. In this case, depending on the situation, it is a factor that hurts the battery.
[0011]
  As a preventive measure, a method of preventing the generation of a surge voltage by stopping the supply of the charging current during a period when both the switches S111 and S112 are OFF (for example, 100 μsec) can be considered.However, in order to prevent the generation of a surge voltage as in the case of this charging, if it is assumed that no discharge current flows during a period when both switches S111 and S112 are OFF during discharging, current cannot be taken during that time. Depending on the conditions on the load side, there is a case where it is always necessary to take out the current. In this case, it is necessary to avoid a situation where the current is not output, even temporarily.
[0012]
  As another preventive measure, it is conceivable to prevent a surge voltage from being generated by providing a surge absorbing circuit (for example, a snubber circuit). However, as the surge absorbing circuit is provided, the loss increases, and the capacity of the battery cannot be fully utilized during charging / discharging. Therefore, it is desirable to avoid the use of surge absorbing circuits.
[0013]
  Non-Patent Document 1 discloses removal of a deteriorated battery in a series connection system. In the circuit of Non-Patent Document 1, a switch including a parallel diode is connected in series with a battery, and a parallel switch is further connected in parallel with the series connection of the battery and the switch. When supplying power to a load, the switch is closed and the diode is shorted. When the battery is charged, the switch is opened and the diode becomes conductive, and charging current is supplied through the diode. When the battery is removed as a deteriorated battery, the parallel switch is closed.
[Non-Patent Document 1]
K. Harada, S. Taniguchi, K. Adachi, G. Ariyoshi, Y. Kawata, "On the Removing of a Less Quality Battery from a Series-Connected System", 22nd International Telecommunications Energy Conference INTELEC 2000, (2000.09.10) , p.761-764
[0014]
[Problems to be solved by the invention]
An object of the present invention is to provide a charge / discharge circuit for a series-connected battery group that can eliminate a deteriorated battery or equalize a voltage without interrupting a charge / discharge operation with a simple configuration.
[0015]
Another object of the present invention is to provide a charge / discharge circuit for a series-connected battery group that can eliminate a deteriorated battery or equalize voltage without interrupting the charge / discharge operation with a simple configuration. .
[0016]
[Means for Solving the Problems]
[Means for Solving the Problems] will be described below using the numbers and symbols used in [Embodiments of the Invention]. These numbers and symbols are added to clarify the correspondence between the description of [Claims] and the description of [Mode for carrying out the invention]. It should not be used to interpret the technical scope of the described invention.
[0017]
The charge / discharge circuit of the battery group connected in series according to the present invention includes a first diode (Dn1) arranged in a forward direction with respect to a charging current (Ir) and a first diode connected in parallel to the first diode (Dn1). A battery group in which a plurality of series units each including a first switching assembly including a switch (Sn1) and a battery (Bn) are connected in series, and arranged in a direction opposite to the charging current (Ir) A second switching assembly connected in parallel to the series unit; and a second switch (Sn2) connected in parallel to the second diode (Dn2) and the second diode (Dn2),
When the battery voltage of the first battery in series (B1) becomes equal to or higher than a predetermined value during charging, the first switch (S11) of the first battery in series is turned OFF, and then the first switch And a control unit that turns on the second switch (S12) of the second switching assembly connected in parallel to the single series unit to bypass the battery (B1) of the first single series unit.
[0018]
In the charging / discharging circuit of the battery group connected in series according to the present invention, the control unit is configured to output the second series when the battery voltage of the second battery (B1) in the series alone becomes a predetermined value or less during discharging. The single first switch (S11) is turned off, and then the second switch (S12) of the second switching assembly connected in parallel to the second single series unit is turned on and the second switch is turned on. The battery (B1) in series is bypassed.
[0019]
The charging / discharging circuit of the series-connected battery group of the present invention includes a first MOS-FET (Sn1) arranged so that the first body diode is formed in the forward direction with respect to the charging current (Ir). A battery group in which a plurality of single series connected to the battery (Bn) are connected in series, and the second body diode is formed in the opposite direction with respect to the charging current (Ir). The first series when the battery voltage of the second MOS-FET (Sn2) connected in parallel to the single series and the battery (B1) of the first single series at the time of charging exceeds a predetermined value. The single first MOS-FET (S11) is turned off, and then the second MOS-FET (S12) connected in parallel to the first series single is turned on and the first series single is turned on. To bypass the battery (B1) And a control unit.
[0020]
In the charging / discharging circuit of the battery group connected in series according to the present invention, the control unit is configured to output the second series when the battery voltage of the second battery (B1) in the series alone becomes a predetermined value or less during discharging. The single first MOS-FET (S11) is turned OFF, and then the second MOS-FET (S12) connected in parallel to the second serial single is turned ON to turn the second serial single The battery (B1) is bypassed.
[0021]
In the charging / discharging circuit of the battery group connected in series according to the present invention, the operation reference when the control unit bypasses the battery (B1) is that the battery voltage of each battery (Bn) of the battery group is a predetermined value. It is determined by whether or not it is reached.
[0022]
In the charging / discharging circuit of the battery group connected in series according to the present invention, the operation reference when the control unit bypasses the battery (B1) is determined by the voltage difference between the two batteries (Bn) included in the battery group. Is done.
[0023]
DETAILED DESCRIPTION OF THE INVENTION
One embodiment of the invention is described.
[0024]
With reference to FIG. 1, a bypass circuit of a lithium secondary battery will be described as an embodiment of a charge / discharge circuit of a series-connected battery group of the present invention.
[0025]
When batteries are used for power storage and electric vehicles, it is necessary to connect a plurality of batteries in series and use them as an assembled battery in order to increase electricity storage capacity. However, in actuality, when batteries are connected in series, overcharge or overdischarge of the battery occurs during charging / discharging due to mixing of deteriorated batteries, variations of individual batteries, or the like. In the present invention, in order to solve these problems, the following method is adopted.
[0026]
As shown in FIG. 1, diodes D11, D12,... Dn1, Dn2 are provided in parallel with the switches S11, S12,. The diodes D11,... Dn1 are arranged in the forward direction with respect to the charging current. The diodes D12,... Dn2 are arranged in the forward direction with respect to the discharge current.
[0027]
In FIG. 1, a battery group is formed by connecting batteries Bn in series via a first switching assembly including a diode Dn1 arranged in the forward direction with respect to the charging current and a switch Sn1 connected in parallel thereto. It is composed.
The second switching assembly is connected in parallel to a single unit formed by connecting the first switching assembly and the battery Bn, and in parallel with the diode Dn2 disposed in the opposite direction to the charging current. And a connected switch Sn2.
[0028]
First, an operation for bypassing the battery B1 during charging will be described.
[0029]
First, in normal times when bypass is not performed, the switch S11 is ON, and the charging current flows to the battery B1 via the switch S11.
[0030]
Next, when the battery voltage of the battery B1 becomes equal to or higher than a predetermined voltage, the switch S11 is turned off. When the switch S11 is turned OFF, the charging current flows to the battery B1 via the diode D11 (at this time, the charging to the battery B1 is continued).
[0031]
Next, when the switch S12 is turned on, since the on-voltage of the switch S12 is smaller than the turn-on voltage of the diode D11, the charging current flows through the switch S12, and the battery B1 is bypassed. At this time, the diode D11 is reverse-biased by the battery B1, and the conduction of the diode D11 is turned off.
[0032]
Next, an operation for bypassing the battery B1 during discharging will be described.
[0033]
First, in normal times when bypass is not performed, the switch S11 is ON, and the discharge current flows from the positive terminal side of the battery B1 to an external load (not shown) via the switch S11.
[0034]
Next, when the battery voltage of the battery B1 becomes equal to or lower than a predetermined voltage, the switch S11 is turned off. When the switch S11 is turned OFF, the discharge current flows to the external load via the diode D12. Thereby, even if the battery B1 is bypassed during discharging, a current path for the discharging current is secured.
[0035]
The diode D12 has a high turn-on voltage, and has a large loss when a discharge current flows through the diode D12 for a long time. This becomes a problem when the discharge current is a large current (for example, about 20 A). Therefore, the switch S12 is turned on and a discharge current is passed through the switch S12. As a result, the loss is effectively suppressed as compared with the case of passing through the diode D12.
[0036]
From the above operation, a current path while bypassing the battery B1 during charging and discharging is always ensured, and current continuity is maintained. Therefore, a surge absorption circuit is not necessary, and it is not necessary to stop the supply of charging current.
[0037]
FIG. 2 shows a specific embodiment.
In FIG. 2, members having the same functions as those in FIG.
[0038]
As shown in FIG. 2, the switch unit is composed of a MOS-FET. The MOS-FET has a structure in which a diode portion (this is referred to as a body diode) is formed from the source to the drain, so that the circuit configuration is simplified when it is used. The body diode has the same current capacity as the MOS-FET.
[0039]
The MOS-FETs S12 and Sn2 function as bypass switches.
Further, when the MOS-FETs S11, S12,... Sn1, Sn2 are turned on, the direction of current flow may be from the drain to the source or from the source to the drain, and thus functions as a bidirectional switch. be able to. In FIG. 2, one MOS-FET is provided, but in the case of a large current, the MOS-FET can be provided in multiple stages in parallel.
[0040]
Next, the operation of this embodiment will be described.
[0041]
First, an operation for bypassing the battery B1 during charging will be described.
[0042]
First, in a normal time when bypass is not performed, a bias voltage is applied to the gate of the MOS-FET S11, the MOS-FET S11 is turned on, and the charging current is supplied to the battery B1 via the MOS-FET S11. Flowing.
[0043]
Next, when the battery voltage of the battery B1 becomes equal to or higher than a predetermined voltage (for example, 4, 2V), a reverse bias voltage is applied to the gate of the MOS-FET S11 to turn off the MOS-FET S11. When the MOS-FET S11 is turned off, the charging current flows to the battery B1 via the body diode of the MOS-FET S11 (at this time, the charging to the battery B1 is continued).
[0044]
Next, when a predetermined voltage is applied to the gate of the MOS-FET S12 and the MOS-FET S12 is turned on, the on-voltage of the MOS-FET S12 is smaller than the turn-on voltage of the body diode of the MOS-FET S11. The charging current flows through the MOS-FET S12, and the battery B1 is bypassed.
[0045]
Next, an operation for bypassing the battery B1 during discharging will be described.
[0046]
First, during normal times when bypass is not performed, a bias voltage is applied to the gate of the MOS-FET S11, the MOS-FET S11 is turned on, and the discharge current is supplied from the positive terminal side of the battery B1 to the MOS-FET S11. To an external load (not shown).
[0047]
Next, when the battery voltage of the battery B1 becomes a predetermined voltage (for example, 3, 3V) or less, a reverse bias voltage is applied to the gate of the MOS-FET S11 to turn off the MOS-FET S11. When the MOS-FET S11 is turned off, the discharge current flows to the external load via the body diode of the MOS-FET S12. Thereby, even if the battery B1 is bypassed during discharging, a current path for the discharging current is secured.
[0048]
The body diode of the MOS-FET S12 has a high turn-on voltage, and has a large loss when a discharge current flows through the body diode for a long time. Therefore, a bias voltage is applied to the gate of the MOS-FET S12, the MOS-FET S12 is turned on, and a discharge current flows through the MOS-FET S12. Thereby, the loss of the discharge current is effectively suppressed as compared with the case where the body diode of the MOS-FET S12 is used.
[0049]
From the above operation, a current path while bypassing the battery B1 during charging and discharging is always ensured, and current continuity is maintained. Therefore, a surge absorption circuit is not necessary, and it is not necessary to stop the supply of charging current.
[0050]
Since the turn-on voltage of the body diode of the MOS-FET is generally high, if the current flows through the body diode for a predetermined time or more, the MOS-FET may be damaged due to heat generation or the like. In this embodiment, the charging current flows through the body diode of the MOS-FET S11 is only a short time required for switching from the MOS-FET S11 being turned off until the MOS-FET S12 is turned on. (For example, several hundred μsec). Similarly, the time during which the discharge current flows through the body diode of the MOS-FET S12 is only a short time required for switching from when the MOS-FET S11 is turned off until the MOS-FET S12 is turned on (for example, , Several hundred μsec). Therefore, in this embodiment, there is no possibility that the MOS-FETs S11 and S12 are damaged by the current flowing through the body diode.
[0051]
In this way, in this embodiment, the current flows through the body diode for a short time, and there is no disadvantage associated with its use, so there is no need to use a diode (individual element) other than the body diode.
[0052]
In FIG. 2, the switch portion is on the positive terminal side of the battery, but there is no problem if the switch portion is on the negative terminal side of the battery as shown in FIG.
[0053]
The bypass operation can be performed as follows. A description will be given separately for charging and discharging. There are two methods (1) and (2) for each time point of charge and discharge.
[0054]
[1] When charging
(1) Each battery voltage is measured, and when the voltage reaches a predetermined value, the battery is bypassed. The bypass is released when discharging.
(2) Each battery voltage is measured, two battery voltages are compared, and when the difference reaches a specified voltage, a battery having a high voltage is bypassed. When the battery voltage of the battery having a low battery voltage increases by the difference, the bypass of the bypassed battery is released.
[0055]
[2] During discharge
(1) Each battery voltage is measured, and when the voltage reaches a predetermined value, the battery is bypassed. The bypass is released when charging.
(2) Each battery voltage is measured, two battery voltages are compared, and when the difference reaches a specified voltage, a battery having a low voltage is bypassed. When the battery voltage of the battery having a high battery voltage drops by the difference, the bypass of the bypassed battery is released.
[0056]
Next, (1) of the above [1] will be specifically described with reference to FIG. 4 and FIG. Here, the battery to be bypassed is described as being removed as a deteriorated battery. However, it goes without saying that even a battery that should be bypassed may be used as it is without being removed as a deteriorated battery.
[0057]
FIG. 4 is an operation flow diagram during charging when four batteries are used, and FIG. 5 is a configuration diagram of a circuit for removing a deteriorated battery during charging.
[0058]
In FIG. 5, in the initial state at the time of charging, the MOS-FET Sn1 of the first switching assembly is turned on, and the MOS-FET Sn2 of the switch Sn2 of the second switching assembly is turned off.
[0059]
When charging from the charging device, the MOS-FET Sn1 of the first switching assembly is turned on, a charging current is passed through the MOS-FET Sn1, and the voltage of each battery Bn is monitored (S1). As a result of the monitoring, when a deteriorated battery showing an abnormal voltage increase is detected (S2), the MOS-FET Sn1 of the first switching assembly is turned off, and then the switch of the second switching assembly is turned off. When the MOS-FET Sn2 of Sn2 is turned ON (S3), the above-mentioned deteriorated battery is excluded without stopping the system by bypassing the charging current, and then the deteriorated battery is replaced with a new battery and all the batteries have the same voltage. The MOS-FET Sn2 of the second switching assembly is turned off, and then the MOS-FET Sn1 of the first switching assembly is turned on (S4) to return to the normal state.
[0060]
Next, (1) of the above [2] will be described in detail with reference to FIGS. Here, it is assumed that the battery to be bypassed is removed as a deteriorated battery. However, it goes without saying that even a battery to be bypassed may be used as it is without being removed as a deteriorated battery.
[0061]
FIG. 6 is an operation flow diagram (removal circuit) at the time of discharging when four batteries are used, and FIG. 7 is a configuration diagram of a circuit for removing a deteriorated battery at the time of discharging.
[0062]
In FIG. 7, in the initial state at the time of discharge, the MOS-FET Sn1 of the first switching assembly is turned on, and the MOS-FET Sn2 of the switch Sn2 of the second switching assembly is turned off.
[0063]
At the time of discharging to the load, the MOS-FET Sn1 of the first switching assembly is turned on, a discharge current is passed through the MOS-FET Sn1, and the voltage of each battery Bn is monitored (S5). As a result of the monitoring, when a deteriorated battery showing an abnormal voltage drop is detected (S6), the MOS-FET Sn1 of the first switching assembly is turned off, and then the switch of the second switching assembly is turned off. When the MOS-FET Sn2 of Sn2 is turned on (S7), the above-mentioned deteriorated battery is excluded without stopping the system by bypassing the discharge current, and then the deteriorated battery is replaced with a new battery, and all the batteries have the same voltage. The MOS-FET Sn2 of the second switching assembly is turned off, and then the MOS-FET Sn1 of the first switching assembly is turned on (S8) to return to the normal state.
[0064]
Next, with reference to FIG. 8 to FIG. 10, (2) of the above [1] will be specifically described.
[0065]
FIG. 8 is a voltage equalization circuit diagram for bypassing the deteriorated battery during charging when four batteries are used for the equalization operation of the deteriorated battery, and FIG. 9 is a graph showing the relationship between time and voltage at that time. FIG. 10 is a flowchart showing the operation at that time.
[0066]
In FIG. 8, it is assumed that the battery B1 is a deteriorated battery having a higher voltage than the other batteries among the batteries B1, B2, B3, and B4 connected in series (see FIG. 9). The charging current of this circuit is Ir. Here, in order to balance the voltage V1 of the deteriorated battery with the voltages of the other batteries, the MOS-FET Sn1 of its first switching assembly is turned off and then the switch Sn2 of its second switching assembly is turned off. The MOS-FET Sn2 is turned on (S9 in FIG. 10). At that time, the voltage V1 of the battery B1 drops to V1 'because the voltage drop due to the internal resistance becomes zero. Here, the voltage V1 at t1 is kept constant at V1 '. After that, when the value of V2 at t2 and V1 equal to V1 (t1) at t1 (S10), the MOS-FET Sn2 of its second switching assembly is turned off, and then The MOS-FET Sn1 of the first switching assembly is turned on (S11), and then the voltage V1 is restored to this voltage. After t2, V1 is charged with the same voltage as V2, so that balanced charging is possible. This bypass operation equalizes the voltage by repeating the bypass operation of the deteriorated battery many times even for a new voltage imbalance occurring after t2.
[0067]
In the flowchart of FIG. 10, the average voltage Vav is obtained excluding the battery having the highest voltage, and the average voltage Vav is compared with the highest voltage to equalize the voltage. However, the method is limited to this method. Not. For example, the voltages of two arbitrary (adjacent) batteries are compared, and when the difference reaches a specified voltage, a battery having a high voltage is bypassed. When the battery voltage of the battery having a low battery voltage increases by the difference, the bypass of the battery bypassed can be canceled.
[0068]
Next, with reference to FIG. 11 to FIG. 13, (2) of [2] will be specifically described.
[0069]
FIG. 11 is a voltage equalization circuit diagram for bypassing a deteriorated battery during discharging, FIG. 12 is a graph showing the relationship between time and voltage at that time, and FIG. 13 is a flowchart showing the operation at that time. It is.
[0070]
In FIG. 11, B1, B2, B3, and B4 are batteries connected in series, and it is assumed that the battery B1 is a deteriorated battery having a lower voltage than other batteries (see FIG. 12). The discharge current of this circuit is Io. Here, in order to balance the voltage V1 of the deteriorated battery with the voltages of the other batteries, the MOS-FET S11 of its first switching assembly is turned off at t1, and then the second switching assembly of its second switching assembly. The MOS-FET Sn2 is turned on (S12 in FIG. 13). At that time, since the battery B1 is opened, the voltage V1 rises to V1 ″. Here, the voltage V1 at t1 is kept constant at V1 ″. After that, when the value of V2 at t2 and V1 equal to V1 (t1) at t1 (S13), the MOS-FET Sn2 of its second switching assembly is turned off, and then The MOS-FET Sn1 of the first switching assembly is turned on (S14), and then the voltage V1 is restored to this voltage. After t2, V1 is discharged at the same voltage as V2, so a balanced discharge is possible. This bypass operation equalizes the voltage by repeating the bypass operation of the deteriorated battery many times even for a new voltage imbalance occurring after t2.
[0071]
In the flowchart of FIG. 13, the average voltage Vav is obtained except for the battery having the lowest voltage, and the average voltage Vav is compared with the lowest voltage to equalize the voltage. However, the method is limited to this method. Not. For example, the voltages of any two (adjacent) batteries are compared, and if the difference reaches a specified voltage, the battery with the lower voltage is bypassed. The bypass of the battery bypassed when the battery voltage of the battery having a high battery voltage drops by the difference can be canceled.
[0072]
Instead of using the body diode of the MOS-FET, an external diode can be used. When an external diode is used, a switch other than a MOS-FET can be used as the switch. As the switch, in addition to a semiconductor element such as a MOS-FET, a relay (mechanical switch), IGBT, thyristor, GTO, power transistor, or the like may be used.
[0073]
According to this embodiment, it is possible to provide a bypass circuit in which uniform charging and uniform discharging are possible for batteries connected in series, and current continuity is ensured.
[0074]
【The invention's effect】
According to the charging / discharging circuit of the battery group connected in series according to the present invention, it is possible to exclude the deteriorated battery or equalize the voltage without interrupting the charging / discharging operation with a simple configuration.
[Brief description of the drawings]
FIG. 1 is a circuit diagram showing a configuration of an embodiment of a charge / discharge circuit of a battery group connected in series according to the present invention.
FIG. 2 is a circuit diagram showing a specific example of an embodiment of a charge / discharge circuit of a series-connected battery group of the present invention.
FIG. 3 is a circuit diagram showing another specific example of the embodiment of the charge / discharge circuit of the battery group connected in series according to the present invention.
FIG. 4 is a flowchart showing an operation at the time of charging in a specific example of the embodiment of the charging / discharging circuit of the battery group connected in series according to the present invention.
FIG. 5 is a circuit diagram of a circuit for removing a deteriorated battery during charging in a specific example of an embodiment of a charging / discharging circuit of a series-connected battery group of the present invention.
FIG. 6 is a flowchart showing an operation at the time of discharging in a specific example of the embodiment of the charging / discharging circuit of the series-connected battery group of the present invention.
FIG. 7 is a circuit diagram of a circuit for removing a deteriorated battery during discharge in a specific example of an embodiment of a charge / discharge circuit of a battery group connected in series according to the present invention.
FIG. 8 is a circuit diagram for explaining a voltage equalization method for bypassing a deteriorated battery during charging in a specific example of an embodiment of a charging / discharging circuit of a series-connected battery group of the present invention.
FIG. 9 is a graph showing time and battery voltage when a voltage equalization method for bypassing a deteriorated battery during charging is performed in a specific example of an embodiment of a charge / discharge circuit of a series-connected battery group of the present invention; It is the graph which showed the relationship.
FIG. 10 is a flowchart showing an operation of a voltage equalization method for bypassing a deteriorated battery during charging in a specific example of an embodiment of a charging / discharging circuit of a series-connected battery group of the present invention.
FIG. 11 is a circuit diagram for explaining a voltage equalization method for bypassing a deteriorated battery at the time of discharge in a specific example of the charge / discharge circuit of the battery group connected in series according to the present invention.
FIG. 12 is a graph showing time and battery voltage when a voltage equalization method for bypassing a deteriorated battery during discharge is performed in a specific example of an embodiment of a charge / discharge circuit of a series-connected battery group of the present invention; It is the graph which showed the relationship.
FIG. 13 is a flowchart showing an operation of a voltage equalization method for bypassing a deteriorated battery at the time of discharge in a specific example of the charge / discharge circuit of the series-connected battery group of the present invention.
FIG. 14 is a circuit diagram showing a configuration in which a large number of batteries are connected in series.
FIG. 15 is a circuit diagram showing a configuration of a prior art.
FIG. 16 is a circuit diagram showing a configuration of another prior art.
[Explanation of symbols]
B1 battery
B2 battery
B3 battery
B4 battery
Bn battery
D drain
G Gate
D11 Diode
D12 Diode
Dn1 diode
Dn2 diode
Ir charging current
Io discharge current
S source
S11 MOS-FET (Switch)
S12 MOS-FET (Switch)
S21 MOS-FET (Switch)
S22 MOS-FET (Switch)
S31 MOS-FET (Switch)
S32 MOS-FET (Switch)
S41 MOS-FET (Switch)
S42 MOS-FET (Switch)
Sn1 MOS-FET (switch)
Sn2 MOS-FET (switch)
S111 switch
S112 switch
S1n1 switch
S1n2 switch
V1 battery voltage
V2 battery voltage
V3 battery voltage
V4 battery voltage

Claims (10)

A plurality of series units each including a first switching assembly including a first diode disposed in a forward direction with respect to a charging current and a first switch connected in parallel to the first diode and a battery. A group of batteries connected in series;
A second switching assembly comprising a second diode disposed in a reverse direction to the charging current and a second switch connected in parallel to the second diode, and connected in parallel to the series unit;
When the battery voltage of the first series single battery is less than a first predetermined value during charging, the first switch of the first single series is turned on and in parallel with the first single series. and said second switch connected to said second switching assembly to OFF, said when the battery voltage of the battery of the first series alone during charge becomes the first predetermined value or more Turn off the first switch of the first series unit, and then turn on the second switch of the second switching assembly connected in parallel to the first series unit. A control unit for bypassing the battery ,
When both the first switch of the first series unit and the second switch of the second switching assembly connected in parallel to the first series unit are turned off, the first series unit Providing a path through which the first diode of the first switching assembly is energized to supply the charging current to the first series of cells;
Thereafter, when the second switch of the second switching assembly is turned ON, the first diode is reverse-biased by the battery in the first series unit, thereby the first unit in the series. A charging / discharging circuit of a series-connected battery group in which conduction of the first diode of the first switching assembly is automatically turned off . In the charge / discharge circuit of the battery group connected in series according to claim 1,
The control unit turns on the first switch of the second series unit and turns on the second switch when the battery voltage of the second series unit battery exceeds a second predetermined value during discharging. said second switch of the second switching assembly connected in parallel with the series itself is OFF, the second battery voltage of the battery series alone becomes equal to or less than the second predetermined value during discharge said second series single first switch to OFF when subsequently said oN the second switch of the second of the series itself is connected in parallel a second switching assembly first A charge / discharge circuit for a series-connected battery group that bypasses the batteries of two series units. A battery group in which a plurality of single units formed by connecting a first MOS-FET and a battery are arranged in series so that the first body diode is formed in a forward direction with respect to a charging current;
A second MOS-FET arranged so that the second body diode is formed in the opposite direction to the charging current and connected in parallel to the single unit;
When the battery voltage of the battery in the first series unit is less than a first predetermined value during charging, the first MOS-FET in the first series unit is turned on and the first series unit is turned on. OFF the connected second MOS-FET in parallel with said first series when the battery voltage of the battery of the first series alone during charge becomes the first predetermined value or more The single first MOS-FET is turned off, and then the second MOS-FET connected in parallel to the first series single is turned on to bypass the first series single battery. and a control unit,
When both the first MOS-FET of the first series unit and the second MOS-FET connected in parallel to the first series unit are turned off, the first series unit of the first MOS-FET is turned off. Providing a path through which the first body diode of the first MOS-FET is turned on to supply the charging current to the first battery in series;
Thereafter, when the second MOS-FET is turned on, the on-voltage of the second MOS-FET is smaller than the turn-on voltage of the first body diode, so that the first serial unit first A series-connected battery charging / discharging circuit in which the conduction of the first body diode of the MOS-FET is automatically turned off . In the charge / discharge circuit of the battery group connected in series according to claim 3 ,
The controller turns on the first MOS-FET of the second series unit when the battery voltage of the second series unit battery exceeds a second predetermined value at the time of discharge, when the battery voltage of said battery of said second series alone becomes equal to or less than the second predetermined value to OFF said second series single said first MOS-FET, then the second A charge / discharge circuit for a series-connected battery group that turns on the second MOS-FET connected in parallel to a single series unit to bypass the second series single unit battery. A plurality of series units each including a first switching assembly including a first diode disposed in a forward direction with respect to a charging current and a first switch connected in parallel to the first diode and a battery. A group of batteries connected in series;
A second switching assembly comprising a second diode disposed in a reverse direction to the charging current and a second switch connected in parallel to the second diode, and connected in parallel to the series unit;
With control
With
At the time of charging, the control unit defines a difference between the battery voltage of the first series unit battery and the battery voltage of the second series unit battery adjacent to the first series unit. The first switch of the first series unit and the second series unit are turned on and the first series unit and the second series unit are connected in parallel. The second switch of the second switching assembly is turned OFF, and the difference between the battery voltage of the first series unit battery and the battery voltage of the second series unit battery becomes the specified voltage. In the case of reaching, the first switch of one of the first series unit and the second series unit having the higher battery voltage of the battery is turned off, and then the first series unit is parallel to the one series unit. Connected to And ON the second switch of the second switching assembly to bypass the battery series single said one,
When both the first switch of the one series unit and the second switch of the second switching assembly connected in parallel to the one series unit are turned off, the first unit of the one series unit is turned off. Providing a path through which the first diode of one switching assembly conducts to supply the charging current to the one unit battery in series;
Thereafter, when the second switch of the second switching assembly of the one series unit is turned on, the first diode is reverse-biased by the battery of the one series unit, thereby The conduction of the first diode of the first switching assembly in a series unit is automatically turned off.
Charge / discharge circuit for series connected battery group. A battery group in which a plurality of single units formed by connecting a first MOS-FET and a battery are arranged in series so that the first body diode is formed in a forward direction with respect to a charging current;
  The second body diode is arranged in the opposite direction to the charging current. A second MOS-FET connected in parallel to the series unit;
  With control
With
  At the time of charging, the control unit is configured such that a difference between the battery voltage of the first series unit battery and the battery voltage of the second series unit battery adjacent to the first series unit is When the specified voltage is not reached, the first MOS-FET of the first series unit and the second series unit are turned on and connected in parallel to the first series unit and the second series unit. The second MOS-FET thus turned off is turned OFF, and the difference between the battery voltage of the first series unit battery and the battery voltage of the second series unit battery reaches the specified voltage. In this case, the first MOS-FET of one of the first series unit and the second series unit having the higher battery voltage of the battery is turned off, and then the one series unit is turned off. Connected in parallel to the first And the MOS-FET is turned ON to bypass the battery series single said one,
  When both of the first single MOS-FET in series and the second MOS-FET connected in parallel to the single single series are turned off, the first single single MOSFET is turned off. Providing a path through which the first body diode of the MOS-FET is conducted to supply the charging current to the one battery in series;
  Thereafter, when the second MOS-FET of the one series unit is turned on, the on-voltage of the second MOS-FET is smaller than the turn-on voltage of the first body diode. The conduction of the first body diode of the first MOS-FET in series is automatically turned off.
  Charge / discharge circuit for series connected battery group. A plurality of series units each including a first switching assembly including a first diode disposed in a forward direction with respect to a charging current and a first switch connected in parallel to the first diode and a battery. A group of batteries connected in series;
A second switching assembly connected in parallel to the series unit, comprising: a second diode disposed in a direction opposite to the charging current; and a second switch connected in parallel to the second diode;
A method for charging a series-connected battery group comprising:
When the battery voltage of the first series unit battery is less than a predetermined value during charging, the first switch of the first series unit is turned on and connected in parallel to the first series unit Turning off the second switch of the second switching assembly
When the battery voltage of the first series unit battery becomes equal to or higher than the predetermined value during charging, the first switch unit of the first series unit is turned off, and then the first series unit unit is turned off. Turning on the second switch of the second switching assembly connected in parallel to bypass the battery in the first series unit;
With
When both the first switch of the first series unit and the second switch of the second switching assembly connected in parallel to the first series unit are turned off, the first series unit Providing a path through which the first diode of the first switching assembly is energized to supply the charging current to the first series of cells;
Thereafter, when the second switch of the second switching assembly is turned ON, the first diode is reverse-biased by the battery in the first series unit, thereby the first unit in the series. The conduction of the first diode of the first switching assembly is automatically turned off.
Charging method. Arranged so that the first body diode is formed in the forward direction with respect to the charging current A battery group in which a plurality of single series units each formed by connecting a first MOS-FET and a battery are connected in series;
  A second MOS-FET arranged so that the second body diode is formed in the opposite direction to the charging current, and connected in parallel to the single unit;
A method for charging a series-connected battery group comprising:
  When the battery voltage of the first battery in series is less than a first predetermined value during charging, the first MOS-FET in the first series alone is turned on and the first series is turned on. Turning off the second MOS-FET connected in parallel to a single unit;
  When the battery voltage of the first series unit battery becomes equal to or higher than the first predetermined value at the time of charging, the first series unit first MOS-FET is turned off, and then the first series unit unit is turned off. Turning on the second MOS-FET connected in parallel to the series unit and bypassing the battery of the first series unit;
With
  When both the first MOS-FET of the first series unit and the second MOS-FET connected in parallel to the first series unit are turned off, the first series unit of the first series unit is turned off. The first body diode of the first MOS-FET is turned on to provide a path for supplying the charging current to the first battery in series.
  Thereafter, when the second MOS-FET is turned on, the on-voltage of the second MOS-FET is smaller than the turn-on voltage of the first body diode, so that the first serial unit first The first body diode of the MOS-FET is automatically turned off.
  Charging method. A plurality of series units each including a first switching assembly including a first diode disposed in a forward direction with respect to a charging current and a first switch connected in parallel to the first diode and a battery. A group of batteries connected in series;
A second switching assembly connected in parallel to the series unit, comprising: a second diode disposed in a direction opposite to the charging current; and a second switch connected in parallel to the second diode;
A method for charging a series-connected battery group comprising:
When the difference between the battery voltage of the first battery in series and the battery voltage of the second battery in series adjacent to the first battery does not reach a specified voltage during charging. The first switching unit of the first series unit and the second series unit is turned on, and the second switching assembly is connected in parallel to the first series unit and the second series unit. Turning off the second switch of
When the difference between the battery voltage of the first series unit battery and the battery voltage of the second series unit battery reaches the specified voltage during charging, the first series unit And the second switching assembly connected to the one series unit in parallel after turning off the first switch of the series unit having one of the second series units having the higher battery voltage. Turning on the second switch of the battery and bypassing the one battery in series.
With
When both the first switch of the one series unit and the second switch of the second switching assembly connected in parallel to the one series unit are turned off, the first unit of the one series unit is turned off. Providing a path through which the first diode of one switching assembly is energized to supply the charging current to the one unit battery in series;
Thereafter, when the second switch of the second switching assembly of the one series unit is turned on, the first diode is reverse-biased by the battery of the one series unit, thereby The conduction of the first diode of the first switching assembly in a series unit is automatically turned off.
Charging method . A battery group in which a plurality of single units formed by connecting a first MOS-FET and a battery are arranged in series so that the first body diode is formed in a forward direction with respect to a charging current;
  A second MOS-FET arranged so that the second body diode is formed in the opposite direction to the charging current, and connected in parallel to the single unit;
A method for charging a series-connected battery group comprising:
  At the time of charging, the difference between the battery voltage of the first battery in series and the battery voltage of the second battery in series adjacent to the first battery reaches a specified voltage. If not, the first MOS-FET of the first series unit and the second series unit are turned on, and the first series unit and the second series unit are connected in parallel. Turning off the second MOS-FET;
  When the difference between the battery voltage of the first series unit battery and the battery voltage of the second series unit battery reaches the specified voltage during charging, the first series unit And turn off the first MOS-FET of the one series unit having the higher battery voltage of the second series unit, and then connect the second unit connected in parallel to the one series unit. Turning on the MOS-FET to bypass the one battery in series
With
  When both of the first single MOS-FET in series and the second MOS-FET connected in parallel to the single single series are turned off, the first single single MOSFET is turned off. Providing a path through which the first body diode of the MOS-FET is conducted to supply the charging current to the one battery in series;
  Thereafter, when the second MOS-FET of the one series unit is turned on, the ON voltage of the second MOS-FET is smaller than the turn-on voltage of the first body diode, so that the one of the series MOS transistors is turned on. The conduction of the first body diode of the single first MOS-FET is automatically turned off.
  Charging method.

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