JP2013146160A - Charge control system and charge control method of battery pack - Google Patents

Abstract

PROBLEM TO BE SOLVED: To more appropriately charge a secondary battery while suppressing a discharge amount when a plurality of secondary batteries are used as an assembled battery.
SOLUTION: A voltmeter 4 for monitoring a charging voltage of each cell 2, a bypass circuit 3 having a discharging resistor 31 for discharging each cell 2 individually, and each bypass circuit based on a charging voltage of each cell 2. And a controller 6 for controlling 3. The bypass circuit 3 can switch between discharging the small discharge current by operating the entire discharge resistor 31 or discharging a large discharge current by operating a part of the discharge resistor 31. When the charging voltage of 2 is higher than the first predetermined voltage, the cell 2 is discharged with a small discharge current. When the charging voltage of each cell 2 is in a predetermined state, the predetermined cell 2 is discharged with a large discharge current. The bypass circuit 3 is controlled so as to be discharged.
[Selection] Figure 1

Description

  The present invention relates to an assembled battery charge control system and a charge control method for controlling charging of an assembled battery in which a plurality of secondary batteries are connected in series.

  For example, lithium ion secondary batteries have advantages such as high energy density and low self-discharge, and have been used as power sources for small electronic devices such as mobile phones and laptop computers. Furthermore, in recent years, it has been regarded as a promising battery for electric vehicles, and its use as an industrial backup battery is expanding. In use, in order to obtain the voltage and capacity according to the purpose of use, a plurality of lithium-ion cells, which are single cells, are connected in series to form an assembled battery, and further, these assembled batteries are connected in parallel. There is a case. When using such an assembled battery, when the assembled battery voltage reaches the charging completion voltage and the charging of each lithium ion cell is completed, the charging state of each lithium ion cell, that is, the terminal voltage of each lithium ion cell Variations may occur in That is, the charge voltage of some lithium ion cells is high and the battery is overcharged, and in some other lithium ion cells, the charge voltage is low and the battery is undercharged (not fully charged).

  For this reason, when using a lithium ion secondary battery as an assembled battery, there is a technique in which a bypass circuit (resistor) is provided in order to properly charge the terminal voltage of each lithium ion cell as equal as possible without variation. It is known (for example, refer to Patent Document 1). In this technique, a plurality of lithium ion cells are connected in series, and each lithium ion cell is provided with a bypass circuit. When the voltage of a certain lithium ion cell exceeds the upper limit of an appropriate charging voltage range (allowable charging voltage range) during charging, the lithium ion cell is discharged (bypass discharge) by a bypass circuit corresponding to this cell. Thus, the terminal voltage of the lithium ion cell is lowered, and charging of the lithium ion cell having a low voltage is promoted.

Japanese Patent Application Laid-Open No. 2002-064947

  By the way, as resistors used in the bypass circuit as described above, resistors having a constant value are usually used. As a result, when the bypass circuit is turned on, the bypass discharge current value from each lithium ion cell is also constant. However, even if bypass discharge is continued at a constant discharge current value, depending on the state of charge of each lithium ion cell and the internal state (charge acceptance characteristics, etc.), charging of a low voltage lithium ion cell may not be promoted. obtain. On the other hand, if the discharge current is increased uniformly, the lithium ion cell subject to bypass discharge may be in an overdischarged state (low voltage state) or an abnormal temperature rise may occur, and the amount of unnecessary bypass discharge is large. It is not economical.

  Therefore, the present invention provides a charge control system for an assembled battery that allows more appropriate charging while suppressing the discharge amount of each secondary battery when used as an assembled battery in which a plurality of secondary batteries are connected in series. It is another object of the present invention to provide a charge control method.

  In order to achieve the above object, the invention according to claim 1 is an assembled battery charge control system for controlling charging of an assembled battery in which a plurality of secondary batteries are connected in series, wherein each of the secondary batteries A monitoring means for monitoring a charging voltage; an individual discharging means provided in each of the secondary batteries, each having a resistor to discharge the secondary battery individually; and each of the secondary batteries based on a charging voltage of the secondary battery. Control means for controlling the individual discharge means, wherein the individual discharge means causes the entire resistor to act to discharge the secondary battery with a small discharge current or to act on a part of the resistor. Whether the secondary battery is discharged with a large discharge current can be switched, and the control means is configured to discharge the secondary battery with the small discharge when the charging voltage of the secondary battery is higher than a first predetermined voltage. Controlling the individual discharge means to discharge with current, When the charging voltage of the next battery is in a predetermined state, further, it controls the individual discharge means so as to discharge a predetermined secondary battery by the large discharge current, characterized in that.

  According to the present invention, the charging voltage of each secondary battery is monitored by the monitoring means, and when the charging voltage of a certain secondary battery is higher than the first predetermined voltage, the secondary battery is discharged with a small discharge current. Thus, charging of the other secondary battery is promoted. Further, when the charging voltage of each secondary battery is in a predetermined state, the predetermined secondary battery is discharged with a large discharge current.

  According to a second aspect of the present invention, in the charging control system according to the first aspect, when the control unit continues a state in which a charging voltage of a predetermined number of secondary batteries is equal to or lower than a second predetermined voltage for a predetermined time, When the charging voltage of the predetermined number of secondary batteries is equal to or higher than the third predetermined voltage for a predetermined time, when the difference in charging voltage between the secondary batteries is higher than the predetermined difference, and any of the secondary batteries The individual discharge means is controlled to discharge a predetermined secondary battery with the large discharge current in at least one of the cases where the charging voltage of the battery reaches a fourth predetermined voltage or more. .

According to this invention,
(1) When the state where the charging voltage of the predetermined number of secondary batteries is equal to or lower than the second predetermined voltage continues for a predetermined time,
(2) When the state where the charging voltage of the predetermined number of secondary batteries is equal to or higher than the third predetermined voltage continues for a predetermined time,
(3) If the difference in charging voltage between the secondary batteries is greater than or equal to a predetermined difference,
(4) When the charging voltage of any secondary battery reaches or exceeds the fourth predetermined voltage,
In at least one of the cases, the predetermined secondary battery is discharged with a large discharge current. As a result, the predetermined secondary battery is largely discharged, and charging of other secondary batteries is further promoted.

  The invention according to claim 3 is a charge control method for an assembled battery that controls charging of an assembled battery in which a plurality of secondary batteries are connected in series, and whether the secondary battery is discharged by acting as a whole. The secondary battery is discharged by operating a part thereof, a resistor is provided in each secondary battery so as to be switchable, the charging voltage of each secondary battery is monitored, and the secondary battery When the charging voltage is higher than the first predetermined voltage, the entire resistor is operated to discharge the secondary battery with a small discharge current, and when the charging voltage of each secondary battery is in a predetermined state The predetermined secondary battery is discharged with a large discharge current by causing a part of the resistor to act.

  According to a fourth aspect of the present invention, in the charge control method according to the third aspect, when a state where the charging voltage of the predetermined number of secondary batteries is equal to or lower than the second predetermined voltage continues for a predetermined time, the predetermined number of secondary batteries When the state where the charging voltage of the battery is equal to or higher than the third predetermined voltage continues for a predetermined time, when the difference in charging voltage between the secondary batteries is equal to or higher than the predetermined difference, and when the charging voltage of any secondary battery is When at least one of the predetermined voltages of 4 is reached, a predetermined secondary battery is discharged with a large discharge current by causing a part of the resistor to act.

  According to the first and third aspects of the present invention, when the charging voltage of each secondary battery is in a predetermined state, the predetermined secondary battery is discharged with a large discharge current. By setting to an appropriate value according to the above, it becomes possible to charge each secondary battery more appropriately. Moreover, since the secondary battery can be discharged with a small discharge current and a large discharge current, that is, it is not necessary to always discharge the secondary battery with a large discharge current, the discharge amount of the secondary battery can be suppressed. It becomes. As a result, an overdischarge state (low voltage state) or abnormal temperature rise of the secondary battery can be prevented, and a wasteful discharge amount is reduced, which is economical. In addition, since the magnitude of the discharge current is changed by simply switching whether to operate the entire resistor or a part of the resistor, a plurality of resistors are not required, and the configuration can be simplified and the cost can be reduced. .

  According to the second and fourth aspects of the invention, the charging voltage of each secondary battery is set by setting the second predetermined voltage, the third predetermined voltage, the fourth predetermined voltage, and the predetermined difference to appropriate values. If the secondary battery charging voltage varies widely, or if the secondary battery charging voltage does not reach an appropriate value when discharging with a small discharging current, the specified secondary voltage with a large discharging current is required. The battery is discharged. For this reason, charging of a secondary battery with a low charging voltage is further promoted, the voltage of a secondary battery with a high charging voltage drops to an appropriate value, or variations in the charging voltage of each secondary battery converge. It becomes possible to charge each secondary battery more appropriately.

It is an example of the schematic block diagram which shows the state which applied the charge control system of the lithium ion assembled battery which concerns on embodiment of this invention to the DC power supply system. It is a block diagram which shows the bypass circuit of the system of FIG. It is a figure which shows the 1st case which performs the increase bypass discharge in the system of FIG. It is a figure which shows the 2nd case which performs the increase bypass discharge in the system of FIG. It is a 1st example figure which shows the 3rd case which performs an increased bypass discharge in the system of FIG. FIG. 8 is a second example diagram illustrating a third case in which increased bypass discharge is performed in the system of FIG. 1. FIG. 9 is a third example diagram illustrating a third case in which the increased bypass discharge is performed in the system of FIG. 1. It is a figure which shows the characteristic at the time of charging a lithium ion secondary battery with a constant current. It is a figure which shows the recovery charge behavior after discharge by the prior art in the battery system containing an abnormal lithium ion secondary battery. It is a figure which shows the recovery charge behavior after the discharge in the lithium ion secondary battery of this invention by the system of FIG.

  The present invention will be described below based on the illustrated embodiments.

  FIG. 1 is an example of a schematic configuration diagram showing a state in which a charging control system (hereinafter simply referred to as “charging control system”) 1 for a lithium ion battery pack according to an embodiment of the present invention is applied to a DC power supply system. This charging control system 1 is a system that controls charging of a lithium ion battery pack 20 in which a plurality of (for example, 12 cells) lithium ion cells (lithium ion secondary batteries) 2 that are single cells are connected in series.

  This charging control system 1 mainly includes a bypass circuit (individual discharge means) 3 and a voltmeter (monitoring means) 4 provided in each lithium ion cell 2, a single main switch 5, a controller (control means) 6, It has. Each bypass circuit 3 and each voltmeter 4 are connected to a controller 6 so as to be able to communicate (data transmission).

  The bypass circuit 3 bypasses the charging current to the corresponding lithium ion cell 2, and discharges the lithium ion cell 2 individually to lower the voltage. In this embodiment, as shown in FIG. One discharge resistor (resistor) 31 and a discharge switch 32 are provided. Then, it is possible to switch between discharging the cell 2 with a small discharge current by operating the entire discharge resistor 31 or discharging the cell 2 with a large discharge current by operating a part of the discharge resistor 31. ing. Specifically, a discharge switch 32 having a first terminal S1 provided at the open end of the discharge resistor 31 and a second terminal S2 connected to the center of the discharge resistor 31 is a discharge switch 32. The circuit is connected to the resistor 31 in series.

  As will be described later, during normal charging, the first switch S1 or the second terminal S2 is turned on (connected) in response to a closing command from the controller 6 with the discharge switch 32 turned off (opened). To do. As a result, when the first terminal S1 is turned on, the entire discharge resistor 31 acts and the resistance value becomes R1. That is, the resistance value becomes large, the cell 2 is discharged with a small discharge current (normal bypass current value), and the voltage decreases. On the other hand, when the second terminal S2 is turned on, a part of the discharging resistor 31 acts and the resistance value becomes R2. That is, the cell 2 is discharged with a large discharge current (increased bypass current value) with a small resistance value, and the voltage is further lowered. Here, the resistance values R1 and R2 are set so as to achieve the purpose of normal bypass discharge control and increased bypass discharge control which will be described later.

  The voltmeter 4 is connected in parallel to the corresponding lithium ion cell 2, and always measures and monitors the voltage of the lithium ion cell 2 not only during charging or discharging, and transmits the measurement result to the controller 6 in real time. It is. Although not shown in the figure, each has a measuring device for measuring the total voltage, charging current, discharging current, and temperature of each lithium ion cell 2 of the lithium ion assembled battery 20, and the measurement results from these measuring devices are It is transmitted to the controller 6 in real time.

  The main switch 5 is a switch that controls a charging current to the lithium ion assembled battery 20, and is provided in a charging circuit that supplies power to the lithium ion assembled battery 20. That is, it is connected between the AC / DC converter 101 and the lithium ion assembled battery 20 (charging circuit), the electric power from the commercial power source 100 is converted into DC by the AC / DC converter 101, and the lithium ion is passed through the main switch 5. It is supplied to the assembled battery 20. The main switch 5 is in an on (closed) state in normal times.

  A bypass diode 7 is connected in parallel with the main switch 5. The bypass diode 7 has a function of allowing only a current flow from the lithium ion assembled battery 20 and prevents a current from flowing to the lithium ion assembled battery 20. Thereby, the discharge from the lithium ion assembled battery 20 is always possible, and power is supplied from the lithium ion assembled battery 20 to the load facility 102 via the bypass diode 7. Here, the AC / DC converter 101 and the load facility 102 are connected, and in normal times, the power from the commercial power supply 100 is converted into direct current by the AC / DC converter 101 and supplied to the load facility 102. It has become.

The controller 6 is a device that controls each bypass circuit 3 based on the measurement result from each voltmeter 4, and includes normal bypass discharge control and increased bypass discharge control as its main control. In normal bypass discharge control, when the charging voltage of the lithium ion cell 2 is higher than the average charging voltage V _A (first predetermined voltage) in the charged state, the first terminal S1 of the bypass circuit 3 of the cell 2 is set to Turn on. As a result, the entire discharging resistor 31 acts as a large resistance value R1, and the cell 2 is discharged with a normal bypass current value (normal bypass discharge). Here, the average charging voltage V _A is a value obtained by dividing the total charging voltage by the number of cells 2. In this embodiment, the ± allowable error voltage (for example, ± 20 mV) of the average charging voltage V _A is appropriately set. A charging voltage range is set so that the charging voltage of each cell 2 falls within this allowable voltage range. The upper limit of the allowable voltage range is the upper limit allowable voltage V _MAX and the lower limit of the allowable voltage range is the lower limit allowable voltage V _MIN .

  In the increased bypass discharge control, when the charging voltage of each lithium ion cell 2 is in a predetermined state, the second terminal S2 of the bypass circuit 3 of the predetermined cell 2 is turned on. Thereby, the discharge resistor 31 acts as a small resistance value R2, and discharges a predetermined cell 2 with an increased bypass current value (incremental bypass discharge).

Specifically, when any one of the following four conditions is satisfied, the predetermined cell 2 is subjected to increased bypass discharge. The first case is a case where the state where the charging voltage of the predetermined number of cells 2 is equal to or lower than the second predetermined voltage (V _A -β) continues for a predetermined time. That is, as shown in FIG. 3, a cell 2 (eighth cell 2 ₈ in the figure) lower than the average charging voltage V _A by a β voltage or more continuously exists for a predetermined time even in one cell. Here, the β voltage and the predetermined time are determined in such a state that the voltage of the low voltage cell 2 (the eighth cell 2 ₈ in the figure) does not rise only by the normal bypass discharge control (normal bypass current value). Voltage, time, or voltage and time at which the effect of increased bypass discharge is obtained, and is set according to the characteristics, capacity, etc. of the cell 2.

In this case, in this embodiment, the following cell 2 is subjected to increased bypass discharge. That is, a plurality of upper cells 2 having a high charging voltage are targeted. For example, in FIG. 3, the charging voltage with respect to the upper limit allowable voltage fourth cell _{2 4} higher than _{V MAX} and the 9 cell _{2 9,} turns on the second terminal S2 of the bypass circuit 3. At this time, the above normal bypass discharge control is performed for the other cells 2. On the other hand, all the cells 2 whose charging voltage is equal to or higher than the average charging voltage _VA may be targeted for increased bypass discharge.

The second case is a case where a state where the charging voltage of the predetermined number of cells 2 is equal to or higher than the third predetermined voltage (V _A + α) continues for a predetermined time. That is, as shown in FIG. 4, the cell 2 (the ninth cell 2 ₉ in the figure) that is higher than the average charging voltage V _A by α voltage or more is continuously present for a predetermined time even in one cell. Here, the α voltage and the predetermined time are determined in such a state that the voltage of the high voltage cell 2 (the ninth cell 2 ₉ in the figure) does not drop only by the normal bypass discharge control (normal bypass current value). Voltage, time, or voltage and time at which the effect of increased bypass discharge is obtained, and is set according to the characteristics, capacity, etc. of the cell 2.

In this case, the same cell 2 as in the first case is subjected to increased bypass discharge. For example, in FIG. 4, the charging voltage with respect to the upper limit allowable voltage fourth cell _{2 4} higher than _{V MAX} and the 9 cell _{2 9,} turns on the second terminal S2 of the bypass circuit 3.

A third case is a case where the difference in charging voltage between the cells 2 is greater than or equal to a predetermined difference. That is, as shown in FIGS. 5 to 7, the voltage difference between the cell 2 having the lowest charging voltage (the 10th cell 2 ₁₀ in the figure) and the other cell 2 is a predetermined difference X or more. Here, as shown in FIG. 5, lower than the cell 2 ₁₀ charging voltage lower allowable voltage V _MIN of the minimum voltage, when the charging voltage of a predetermined difference X or more cells 2 ₉ is higher than the upper limit allowable voltage V _MAX and, as shown in FIG. 6, lower than the cell 2 ₁₀ charging voltage lower allowable voltage V _MIN of the minimum voltage, when the charging voltage of a predetermined difference X or more cells 2 ₉ is within the allowable voltage range, FIG. 7 as shown in, in the charging voltage is allowable voltage range of the cell 2 ₁₀ of minimum voltage, and the like when the charging voltage of a predetermined difference X or more cells 2 ₉ is higher than the upper limit allowable voltage V _MAX. Further, the predetermined difference X is a voltage at which such a voltage difference determines that the voltage variation is not eliminated only by the normal bypass discharge control (normal bypass current value), or a voltage at which the effect of the increased bypass discharge is obtained. And is set according to the characteristics and capacity of the cell 2.

Also in this case, the cell 2 similar to the first and second cases is subjected to an increased bypass discharge. For example, in the case of Figure 5, with respect to the fourth cell 2 ₄ higher than the charge voltage is an upper limit allowable voltage V _MAX and the 9 cell 2 _9, in the case of FIG. 6, the charging voltage is an upper limit allowable voltage V for high fourth cell _{2 4} than _MAX, likewise in the case of FIG. 7, with respect to the fourth cell _{2 4} higher than the charge voltage is an upper limit allowable voltage _{V MAX} and the 9 cell _{2 9,} a bypass The second terminal S2 of the circuit 3 is turned on.

A fourth case is when the charging voltage of any cell 2 reaches the above V _BS (predetermined voltage 4) bypass start voltage. That is, in the constant current and constant voltage charge in the recovery charge after discharge (power failure), as shown in FIG. 8, the abnormal lithium ion cell 2 continues to increase the charge voltage and reaches the dangerous voltage (upper limit voltage) V _UL . There is a case. When the critical voltage V _UL is reached, the cell 2 may be damaged or broken. Therefore, as shown in FIG. 9, any one of the cells 2 has a charge stop voltage V lower than the dangerous voltage V _UL. At the time point P1 when _T is reached, a measure to stop charging is required. Against this background, increases as the fourth case, the charging voltage of any cell 2, when P2 reaches a predetermined bypass start voltage V _BS is lower than the charge stop voltage V _T, the cell 2 Bypass discharge.

Thus, as shown in FIG. 10, an abnormal voltage of the cell 2 has reached the bypass start voltage V _BS is intended to decrease. Here, in FIG. 8-10, reference numeral _{V g} represents most appropriate value of the charging voltage (target value), for example 4.1 V, the code _{L A} in FIGS. 9 and 10, the average cell voltage 2 shows the charging voltage changes, the code L _MAX represents the charging voltage transition of the voltage highest cell 2, reference numeral L _MIN denotes a charging voltage transition of the voltage lowest cell 2. Further, the bypass start voltage V _BS is usually bypassed discharge control determines that be continued (usually bypass current value) only lowered the voltage by voltage or increasing the bypass discharge, it is determined to reach the charge stop voltage V _T This voltage is set by the characteristics of the cell 2, the capacity, and the like.

  In the above four cases, when the predetermined cell 2 is subjected to increased bypass discharge and the conditions of the corresponding case are not satisfied within a predetermined time, that is, the abnormal voltage of the cell 2 and the charging voltage between the cells 2 When the abnormal variation is resolved, the second terminal S2 being turned on is turned off, and the increased bypass discharge is terminated. On the other hand, if the abnormal voltage of the cell 2 or the abnormal variation in the charging voltage between the cells 2 is not eliminated even after the increased bypass discharge is performed for a predetermined time, an alarm is output and the charging is stopped. Here, the alarm is output by turning on the alarm lamp of the controller 6 or notifying the computer of the management center. In addition, the predetermined time is a time estimated to cause an internal abnormality of the cell 2 or a connection abnormality between the cells 2, or a time that can avoid excessive bypass discharge, and is set according to the characteristics, capacity, etc. of the cell 2. Is done.

  Next, the operation of the charge control system 1 having such a configuration, a charge control method by the charge control system 1 and the like will be described.

  First, power from the commercial power supply 100 is supplied to the lithium ion assembled battery 20, the voltage of each lithium ion cell 2 is constantly monitored by the voltmeter 4, and the measurement result is transmitted to the controller 6 in real time. Then, based on the charging voltage of each cell 2, the normal bypass discharge control and the increased bypass discharge control as described above are performed.

For example, when the charge voltage of the cell 2 becomes higher than the average charge voltage _VA in the float charge state, the first terminal S1 of the bypass circuit 3 of the cell 2 is turned on, and the cell 2 is discharged at the normal bypass current value. (Normally bypass discharge). Thereby, while the voltage of this cell 2 falls, the charge of the other cell 2 is accelerated | stimulated.

  Further, in the float charging state, when the charging voltage of the cell 2 is abnormally low and high for a predetermined time as in the first case, or the charging voltage of the cell 2 is abnormal as in the second case. When the high state continues for a predetermined time, or when the difference in charging voltage between the cells 2 is large as in the third case, the second circuit of the bypass circuit 3 of the predetermined cell 2 as described above. The terminal S2 is turned on and discharged at an increased bypass current value (incremental bypass discharge). That is, these cells 2 are greatly discharged, the voltage of these cells 2 is greatly reduced, and charging of other cells 2 is further promoted.

  On the other hand, for example, when the assembled battery 20 is discharged and recovery charging is performed, if the charging voltage of the cell 2 reaches an abnormal voltage as in the fourth case, the cell 2 is subjected to increased bypass discharge. As a result, as shown in FIG. 10, the voltage of the cell 2 is greatly reduced, and charging of the other cells 2 is further promoted.

  As described above, according to the charging control system 1 and the charging control method, when the charging voltage of the cell 2 is abnormal, when the variation of the charging voltage of each cell 2 is large, or in the normal bypass discharge, For example, when the charging voltage does not fall within the allowable voltage range, the predetermined cell 2 is subjected to increased bypass discharge. For this reason, the charging of the cell 2 with a low charging voltage is further promoted, the voltage of the cell 2 with a high charging voltage falls to the allowable voltage range, or the variation in the charging voltage between the cells 2 converges. Each cell 2 can be charged more appropriately. As a result, the entire assembled battery 20 can be more appropriately charged, the discharge capacity of the entire assembled battery 20 becomes appropriate, and a predetermined discharge time as designed can be secured.

  Further, only when the charging state of the cell 2 is predetermined (abnormal), the battery is discharged with the increased bypass current value, and is normally discharged with the normal bypass current value. That is, the cell 2 is not always discharged with the increased bypass current value. For this reason, the discharge amount of the cell 2 can be suppressed. As a result, an overdischarge state (low voltage state) or abnormal temperature rise of the cell 2 can be prevented, and a wasteful discharge amount is reduced, which is economical. In addition, since the normal bypass current value and the increased bypass current value can be switched with only one discharge resistor 31, a plurality of resistors are not required, and the configuration can be simplified and the cost can be reduced.

  Further, in the first and second cases, the increased bypass discharge is performed when the state in which the charging voltage of the cell 2 is abnormal continues for a predetermined time. That is, when a charging voltage abnormality occurs temporarily, the increased bypass discharge is not performed, so that unnecessary increased bypass discharge can be avoided. On the other hand, in the third and fourth cases, since the increased bypass discharge is performed when the predetermined charging voltage is reached, the abnormal state is resolved early and the entire assembled battery 20 is charged appropriately and early. Is possible.

  Furthermore, even if the increased bypass discharge is performed for a predetermined time, if the abnormal voltage of the cell 2 or the abnormal variation of the charging voltage between the cells 2 is not eliminated, an alarm is output and the charging is stopped. Quick and appropriate response is possible. That is, in such a case, there is a possibility that an abnormality such as an internal short circuit or connection failure may exist in the cell 2, and an alarm output or charging stop is performed, so that quick and proper inspection, cell replacement, etc. are possible. At the same time, it becomes possible to avoid damage to the cell 2 or abnormal temperature rise. On the other hand, when the abnormal voltage of the cell 2 or the abnormal variation of the charging voltage between the cells 2 is resolved within a predetermined time, the increased bypass discharge is terminated, thereby preventing unnecessary discharge of the cell 2. And it becomes possible to maintain the charge condition of the assembled battery 20 whole appropriately.

  Although the embodiment of the present invention has been described above, the specific configuration is not limited to the above embodiment, and even if there is a design change or the like without departing from the gist of the present invention, Included in the invention. For example, in the above embodiment, the bypass circuit 3 includes one discharge resistor 31, but includes two or more discharge resistors, and more variously (finely) depending on the charging voltage of each cell 2. The bypass current value may be changed. In addition to the above four cases, the bypass current value may be changed according to other charging voltages. In addition, regarding the set values of R1 and R2 in FIG. 2, the fixed ratio may be set at the beginning of installation, or the ratio may be variable according to the state of the cell 2 in operation.

  On the other hand, although the case where it has one set of lithium ion assembled battery 20 was demonstrated, it is applicable also when the some assembled battery 20 is connected in parallel. In this case, the charge control system 1 as described above is provided for each assembled battery 20. Moreover, not only the lithium ion cell 2, but in order to eliminate the variation in the charged state between the series cells, it can be widely applied to secondary batteries in general. Furthermore, although the case where the charge control system 1 is applied to a DC power supply system has been described, it can also be applied to an uninterruptible power supply (UPS), a storage battery for automobiles, and the like. Can be applied.

  In FIG. 1, a configuration example including the diode 7 and the switch 5 is shown as a DC power supply system to which the present invention is applied.

1 Lithium ion battery charge control system 2 Lithium ion cell (lithium ion secondary battery)
20 Lithium ion battery 3 Bypass circuit (individual discharge means)
31 Resistance for discharge (resistor)
32 Discharge switch S1 First terminal S2 Second terminal R1 Large resistance value R2 Small resistance value 4 Voltmeter (monitoring means)
5 Main switch 6 Controller (control means)
7 Bypass diode V _A Average charging voltage (first predetermined voltage)
V _MAX upper limit allowable voltage V _MIN lower limit allowable voltage V _A -β Second predetermined voltage V _A + α Third predetermined voltage V _UL dangerous voltage V _T charge stop voltage V _BS bypass start voltage (predetermined voltage of 4)
V _g Target voltage X Predetermined difference

Claims (4)

A charge control system for an assembled battery that controls charging of the assembled battery in which a plurality of secondary batteries are connected in series,
Monitoring means for monitoring the charging voltage of each secondary battery;
Individual discharge means provided in each of the secondary batteries, each having a resistor to discharge the secondary battery individually;
Control means for controlling each individual discharge means based on the charging voltage of each secondary battery;
With
The individual discharge means may cause the entire resistor to act to discharge the secondary battery with a small discharge current, or cause a part of the resistor to act to discharge the secondary battery with a large discharge current, Can be switched,
The control means controls the individual discharge means to discharge the secondary battery with the small discharge current when the charging voltage of the secondary battery is higher than a first predetermined voltage, and each secondary battery When the charging voltage of the battery is in a predetermined state, the individual discharge means is controlled to discharge a predetermined secondary battery with the large discharge current.
An assembled battery charge control system. When the state where the charging voltage of the predetermined number of secondary batteries is equal to or lower than the second predetermined voltage continues for a predetermined time, the control means determines that the charging voltage of the predetermined number of secondary batteries is equal to or higher than the third predetermined voltage. At least one of the cases where the difference in charge voltage between the secondary batteries is greater than or equal to a predetermined difference, and when the charge voltage of any secondary battery has reached or exceeded the fourth predetermined voltage And controlling the individual discharge means to discharge a predetermined secondary battery with the large discharge current,
The assembled battery charging control system according to claim 1. A battery pack charge control method for controlling charging of a battery pack in which a plurality of secondary batteries are connected in series,
Disposing the secondary battery by actuating the whole, or disposing the secondary battery by actuating a part, disposing a resistor in each secondary battery,
Monitoring the charging voltage of each secondary battery,
When the charging voltage of the secondary battery is higher than a first predetermined voltage, the entire resistor is operated to discharge the secondary battery with a small discharge current, and the charging voltage of each secondary battery is predetermined. In the case of a state, a predetermined secondary battery is discharged with a large discharge current by acting a part of the resistor,
A charge control method for an assembled battery. When a state where the charging voltage of the predetermined number of secondary batteries is equal to or lower than the second predetermined voltage continues for a predetermined time, when a state where the charging voltage of the predetermined number of secondary batteries is equal to or higher than the third predetermined voltage continues for a predetermined time, The resistor in at least one of a case where a difference in charging voltage between the secondary batteries is equal to or larger than a predetermined difference and a case where the charging voltage of any secondary battery reaches a fourth predetermined voltage or higher. A predetermined secondary battery is discharged with a large discharge current by acting a part of
The charge control method for an assembled battery according to claim 3.

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