CHARGE AND DISCHARGE CONTROL DEVICE, CHARGE AND DISCHARGE SYSTEM, CHARGE AND DISCHARGE CONTROL METHOD, AND NON-TRANSITORY STORAGE MEDIUM

Information

  • Patent Application
  • 20210226266
  • Publication Number
    20210226266
  • Date Filed
    August 31, 2020
    4 years ago
  • Date Published
    July 22, 2021
    3 years ago
Abstract
According to an embodiment, there is provided a charge and discharge control device that controls charging and discharging of a battery module in which a plurality of cell blocks, each including one or more unit cells, are connected in parallel to one another. A controller of the charge and discharge control device controls a current flowing through each of the cell blocks based on at least one of a current load of each of the cell blocks or a parameter relating to the current load.
Description
CROSS-REFERENCE TO RELATED APPLICATIONS

This application is based upon and claims the benefit of priority from Japanese Patent Application No. 2020-005970, filed Jan. 17, 2020; the entire contents of which are incorporated herein by reference.


FIELD

Embodiments described herein relate generally to a charge and discharge control device, a charge and discharge system, a charge and discharge control method, and a non-transitory storage medium.


BACKGROUND

As information-related apparatuses and communication apparatuses have spread, secondary batteries have widely spread as electric power supplies of the apparatuses. Secondary batteries also have been utilized in the field of electric vehicles (EV) and natural energy. In particular, lithium-ion secondary batteries are widely used, since they have a high energy density and can be downsized. In lithium-ion secondary batteries, a positive electrode active material and a negative electrode active material absorb and release lithium ions, thereby storing and releasing electric energy. When charging, the lithium ions released from the positive electrode are absorbed by the negative electrode. When discharging, the lithium ions released from the negative electrode are absorbed by the positive electrode.


In secondary batteries such as lithium-ion secondary batteries, a plurality of unit cells are electrically connected in series, so that a high voltage and a high capacity are achieved. A battery module, in which a plurality of cell blocks are electrically connected in parallel to one another, may be used as an electric power supply. In this case, each of the cell blocks includes one or more unit cells. If the cell block includes a plurality of unit cells, just a serial connection structure of a plurality of unit cells may be formed in the cell block, or both a serial connection structure and a parallel connection structure of a plurality of unit cells may be formed in the cell block.


In the battery module in which a plurality of cell blocks are connected in parallel, even if the cell blocks use the same type of unit cells and the cell blocks use the same number of unit cells and the same connection structure of the unit cells, there may be variation in the performance of the unit cells, such as in their capacity and internal resistance, between the cell blocks or there may be variation in resistance of a connecting wire between the cell blocks. Therefore, in the battery module, the cell blocks may have different performances. In addition, through repeated charging and discharging, the cell blocks may deteriorate to different degrees, and the performance may vary between the cell blocks, such as their capacity and internal resistance. In the battery module, even if the cell blocks vary in performance, it is necessary to prevent the cell blocks from excessively varying in current load and to suppress the increase in variations in deterioration between the cell blocks.





BRIEF DESCRIPTION OF THE DRAWINGS


FIG. 1 is a schematic diagram showing a charge and discharge system according to a first embodiment.



FIG. 2 is a schematic diagram showing a circuit model of a battery module of the charge and discharge system shown in FIG. 1.



FIG. 3A is a schematic diagram showing voltage characteristics set by calculation using a model of a battery module including two cell blocks, in which open circuit voltage characteristics of the respective cell blocks and a voltage characteristic of the battery module are illustrated.



FIG. 3B is a schematic diagram showing changes in currents flowing through the respective cell blocks relative to an SOC calculated in the calculation of FIG. 3A.



FIG. 3C is a schematic diagram showing changes in current loads of the respective cell blocks relative to an SOC calculated in the calculation of FIG. 3A.



FIG. 4 is a flowchart showing processing performed in charge and discharge control of a battery module by a controller according to the first embodiment.



FIG. 5 is a schematic diagram showing a charge and discharge system according to a second embodiment.



FIG. 6 is a flowchart showing processing performed in charge and discharge control of a battery module by a controller according to the second embodiment.



FIG. 7 is a schematic diagram showing a charge and discharge system according to a third embodiment.



FIG. 8 is a flowchart showing processing performed in charge and discharge control of a battery module by a controller according to the third embodiment.





DETAILED DESCRIPTION

According to an embodiment, there is provided a charge and discharge control device that controls charging and discharging of a battery module in which a plurality of cell blocks, each including one or more unit cells, are connected in parallel to one another. A controller of the charge and discharge control device controls a current flowing through each of the cell blocks based on at least one of a current load of each of the cell blocks or a parameter relating to the current load.


According to one embodiment, there is provided a charge and discharge control method of controlling charging and discharging of a battery module in which a plurality of cell blocks, each including one or more unit cells, are connected in parallel to one another. In the charge and discharge control method, a current flowing through each of the cell blocks is controlled based on at least one of a current load of each of the cell blocks or a parameter relating to the current load.


According to one embodiment, there is provided a non-transitory storage medium storing a charge and discharge control program to be executed by a computer for charging and discharging of a battery module in which a plurality of cell blocks, each including one or more unit cells, are connected in parallel to one another. The charge and discharge control program causes the computer to control a current flowing through each of the cell blocks based on at least one of a current load of each of the cell blocks or a parameter relating to the current load.


Embodiments will be described below with reference to the accompanying drawings.


First Embodiment


FIG. 1 shows a charge and discharge system 1 according to the first embodiment. As shown in FIG. 1, the charge and discharge system 1 includes a battery module 2, a load and an electric power supply (denoted by a reference numeral 3), a current measurement unit (current measurement circuit) 5, a voltage measurement unit (voltage measurement circuit) 6, a charge and discharge control device 7, and a driving circuit 8. The battery module 2 includes a plurality of cell blocks B1 to Bn. In the battery module 2, the cell blocks B1 to Bn are electrically connected to one another in parallel.


Each of the cell blocks B1 to Bn includes one or more unit cells 11. The unit cell 11 is, for example, a secondary battery such as a lithium-ion secondary battery. In the example shown in FIG. 1, in each of the cell blocks B1 to Bn, the unit cells 11 are electrically connected in series, thereby forming a serial connection structure of the unit cells 11. The cell blocks B1 to Bn are the same in the number of unit cells 11 connected in series. In one example, any of the cell blocks B1 to Bn may be formed of only one unit cell 11. In another example, any of the cell blocks B1 to Bn may have a parallel connection structure in which the unit cells 11 are electrically connected in parallel, in addition to the serial connection structure of the unit cells 11.


The battery module 2 can be charged and discharged. The battery module 2 is charged by electric power supplied from the electric power supply. The electric power discharged from the battery module 2 is supplied to a load. The battery module 2 is mounted on an electronic apparatus, a vehicle, a stationary power supply apparatus, etc. A battery independent of the battery module 2, a generator, etc. may be the electric power supply that supplies electric power to charge the battery module 2. An electric motor, a lighting apparatus, etc. may be the load to which the electric power discharged from the battery module is supplied. In one example, an electric motor generator may function as both the electric power supply and the load. The current measurement unit 5 detects and measures a current I flowing through the battery module 2. The voltage measurement unit 6 detects and measures a voltage Vc applied to the battery module 2.


The charge and discharge control device 7 includes a controller 12. The controller 12 constitutes a computer, and includes a processor and a storage medium. The processor includes one of a central processing unit (CPU), a graphics processing unit (GPU), an application specific integrated circuit (ASIC), a microcomputer, a field programmable gate array (FPGA), a digital signal processor (DSP), etc. The storage medium may include an auxiliary storage device in addition to the main storage device such as the memory. The storage medium may be a magnetic disk, an optical disk (CD-ROM, CD-R, DVD, etc.), a magneto-optical disk (MO etc.), a semiconductor memory, etc. In the controller 12, each of the processor and the storage medium may be one or more. The processor of the controller 12 executes a program etc. stored in the storage medium, thereby performing processing. The program to be executed by the processor of the controller 12 may be stored in a computer (server) connected to the processor through a network such as the Internet, or a server etc. in a cloud environment. In this case, the processor downloads the program via the network. In one example, the charge and discharge control device 7 is formed of an integrated circuit (IC) chip or the like.


The controller 12 acquires a measurement value of the current I flowing through the battery module 2 by the current measurement unit 5, and a measurement value of the voltage Vc applied to the battery module 2 by the voltage measurement unit 6. The measurement of the current I by the current measurement unit 5 and the measurement of the voltage Vc by the voltage measurement unit 6 are performed periodically, for example, at a predetermined timing. Thus, the controller 12 periodically acquires the measurement value of the current I and the measurement value of the voltage Vc at the predetermined timing. Accordingly, the change with time (time history) of the current I and the change with time (time history) of the voltage Vc are acquired by the controller 12. Furthermore, the controller 12 controls driving of the driving circuit 8, thereby controlling charging and discharging of the battery module 2. As a result, in each of the charging and discharging of the battery module 2, the current flowing through the battery module 2 is controlled.


The controller 12 also includes a current load determination unit 13 and a charge and discharge control unit 15. The current load determination unit 13 and the charge and discharge control unit 15 execute some of the processing executed by the processor or the like of the controller 12. The current load determination unit 13 performs determination about a current load of each of the cell blocks B1 to Bn. The determination about the current load is periodically performed at a predetermined timing. The charge and discharge control unit 15 controls driving of the driving circuit 8 and controls charging and discharging of the battery module 2 based on the determination result in the current load determination unit 13.



FIG. 2 shows a circuit model of the battery module 2 in which n cell blocks B1 to Bn are connected in parallel to one another. In the model shown in FIG. 2, it is assumed that the voltage of the entire battery module 2 is Vc, and the current flowing through the battery module 2 is I. Furthermore, a charge amount Qk of a cell block Bk (k is any one of 1 to n), an open circuit voltage Vk(Q) of the cell block Bk where the charge amount Qk is a variable, an internal resistance Rk including the wiring of the cell block Bk, and a current ik flowing through the cell block Bk are defined. In the model shown in FIG. 2, the following formulas (1) and (2) are satisfied. The charge amount Q is represented relative to a state of charge (SOC) 0% as a reference (zero). The unit of the charge amount Q is, for example, (mA·h), (A·h), or the like.










V
c

=




i
1



R
1


+


V
1



(


Q
1

+


i
1


dt


)



=


=



i
n



R
n


+


V
n



(


Q
n

+


i
n


dt


)









(
1
)






I
=




k
=
1

n



i
k






(
2
)







In formula (1), dt represents a minute time. When formula (1) and formula (2) are arranged using a primary approximation represented by the following formula (3), the following formulas (4) and (5) are satisfied.











V
k



(


Q
k

+


i
k


dt


)


=



V
k



(

Q
k

)


+



V
k




(

Q
k

)




i
k


dt






(
3
)








[




A
1




-

A
2




0





0




0



A
2




-

A
3







0




0


0



A
3






0





















0


0


0






-

A
n






1


1


1


1


1



]



[




i
1






i
2






i
3











i
n




]


=

[





-


V
1



(

Q
1

)



+


V
2



(

Q
2

)









-


V
2



(

Q
2

)



+


V
3



(

Q
3

)









-


V
3



(

Q
3

)



+


V
4



(

Q
4

)














-


V

n
-
1




(

Q

n
-
1


)



+


V
n



(

Q
n

)







I



]





(
4
)







A
k

=

(


R
k

+



V
k




(

Q
k

)



d

t


)





(
5
)







Thus, currents i1 to in of the cell blocks B1 to Bn can be calculated by using internal resistances R1 to Rn, open circuit voltages V1(Q1) to Vn(Qn), and primary differential values V1′(Q) to Vn′(Qn) at the charge amount Q of the open circuit voltages V1(Q1) to Vn(Qn). Furthermore, in each of the cell blocks B1 to Bn, namely, in the cell block Bk, the current load Pk is defined by the following formula (6).










P
k

=


i
k


F
k






(
6
)







The parameter Fk may be either of a capacity (cell block capacity) such as a charge capacity (full charge capacity) or a discharge capacity of the cell block Bk, and a positive electrode capacity or a negative electrode capacity of the cell block Bk; that is, the parameter representing the internal state of the cell block Bk is used. The charge capacity (full charge capacity) is a charge amount of the cell block Bk from the state of the SOC 0% to the state of the SOC 100%. The discharge capacity is a discharge amount of the cell block Bk from the state of the SOC 100% to the state of the SOC 0%. In the cell block Bk, the state in which the voltage across a positive electrode terminal and a negative electrode terminal is Vα1 is defined as the state of the SOC 0%, and the state in which the voltage across the positive electrode terminal and the negative electrode terminal is Vα2 greater than Vα1 is defined as the state of the SOC 100%.


The positive electrode capacity is the charge amount of the cell block Bk when the charge amount of the positive electrode is increased from an initial charge amount to an upper limit charge amount. The charge amount of the positive electrode in a state in which the positive electrode potential is Vβ1 is defined as the initial charge amount. The charge amount of the positive electrode in a state in which the positive electrode potential is Vβ2, which is higher than Vβ1, is defined as the upper limit charge amount. The negative electrode capacity is the charge amount of the cell block Bk when the charge amount of the negative electrode is increased from an initial charge amount to an upper limit charge amount. The charge amount of the negative electrode in a state in which the negative electrode potential is Vγ1 is defined as the initial charge amount. The charge amount of the negative electrode in a state in which the negative electrode potential is Vγ2, which is lower than Vγ1, is defined as the upper limit charge amount.


In formula (6), when the charge capacity (full charge capacity) of the cell block Bk is used as the parameter Fk, the current load Pk substantially corresponds to a charge rate of the cell block Bk and becomes a value corresponding to the charge capacity (full charge capacity). If the aforementioned discharge capacity is used instead of the charge capacity as the parameter Fk, the current load Pk substantially corresponds to a discharge rate of the cell block Bk and becomes a value corresponding to the discharge capacity.


In the following, explanations will be given for a case in which the battery module 2 includes two cell blocks B1 and B2, namely, n=2. In the model of the cell blocks B1 and B2, the following formula (7) is satisfied from a relationship similar to formula (1).






i
1
R
1
+V
1(Q1+i1dt)=i2R2+V2(Q2+i2dt)  (7)


When formula (7) is arranged using the primary approximation represented by formula (3), the following formula (8) is satisfied.






i
1(R1+V1′(Q1)dt)−i2(R2+V2′(Q2)dt)=V2(Q2)−V1(Q1)  (8)


When i2=I−i1 is substituted into formula (8), formula (9) is satisfied.






i
1(R1+V1′(Q1)dt+R2+V2′(Q′2)dt)=V2(Q2)−V1(Q1)+i(R2+v2′(Q2)dt)  (9)


It is assumed that dt is a minute time. Accordingly, V1′(Q1)dt is approximated to a value that is negligible relative to R1 and V2′ (Q2)dt is approximated to a value that is negligible relative to R2. Therefore, the following formula (10) is satisfied.






i
1(R1+R2)=V2(Q2)−V1(Q1)+IR2  (10)


When i1=I−i2 is substituted into formula (8) in the same manner as in the case where i2=I−i1 is substituted into formula (8), the following formula (11) is satisfied.






i
2(R1+R2)=−V2(Q2)+V1(Q1)+IR1  (11)


By subtracting formula (11) from formula (10), a difference between the current i1 flowing through the cell block B1 and the current i2 flowing through the cell block B2 is calculated as expressed by formula (12).











i
1

-

i
2


=



2


(



V
2



(

Q
2

)


-


V
1



(

Q
1

)



)


+

I


(


R
2

-

R
1


)




(


R
1

+

R
2


)






(
12
)







The value of V2(Q2)−V1(Q1) in the numerator of formula (12) corresponds to a difference between the open circuit voltage of the cell block B1 and the open circuit voltage of the cell block B2. It is assumed that the cell blocks B1 and B2 are cell blocks (batteries) of the same type. It is also assumed that even if the capacities of the cell blocks B1 and B2 differ from each other due to deterioration, the open circuit voltage characteristics (the relation of the open circuit voltage to the charge amount or the SOC) do not substantially vary between the cell blocks B1 and B2. In this case, when the full charge capacity (charge capacity) FCC1 of the cell block B1 and the full charge capacity (charge capacity) FCC2 of the cell block B2, and the open circuit voltage characteristic V of the cell blocks B1 and B2 represented as a function, are defined, formula (13) is satisfied. The open circuit voltage characteristic V is open circuit voltage characteristics of the cell blocks B1 and B2, which are assumed not to substantially vary between the cell blocks B1 and B2.












V
1



(

Q
1

)


=

V


(


Q
1


F

C


C
1



)



,



V
2



(

Q
2

)


=

V


(


Q
2


F

C


C
2



)







(
13
)







When formula (13) is substituted into formula (12), the following formula (14) is satisfied.











i
1

-

i
2


=



2


(


V


(


Q
2


FCC
2


)


-

V


(


Q
1


FCC
1


)



)


+

I


(


R
2

-

R
1


)




(


R
1

+

R
2


)






(
14
)







When the following formula (15) is assumed and formula (15) is substituted into formula (14), the following formula (16) is satisfied.











Q
2


F

C


C
2



=



Q
1


F

C


C
1



+
dQ





(
15
)








i
1

-

i
2


=



2


(


V


(



Q
1


FCC
1


+
dQ

)


-

V


(


Q
1


FCC
1


)



)


+

I


(


R
2

-

R
1


)




(


R
1

+

R
2


)






(
16
)







If the current I and the internal resistances R1 and R2 do not substantially vary, the numerator of formula (16) changes in accordance with the magnitude of the inclination of the open circuit voltage characteristic V, and changes in accordance with the magnitude of the inclination of the voltage relative to the charge amount in each of the cell blocks B1 and B2. Furthermore, the numerator of formula (16) becomes greater as the inclination of the open circuit voltage characteristic V becomes greater.


If the charge current or the discharge current flowing through the battery module 2 is fixed and the inclination of the open circuit voltage characteristic V is fixed, the difference (i1−i2) between the currents i1 and i2 does not vary. Therefore, in each of the cell blocks B1 and B2, a current corresponding to the capacity, such as the full charge capacity (charge capacity), flows. On the other hand, if the inclination of the open circuit voltage characteristic V varies considerably, the difference (i1−i2) between the currents i1 and i2 varies considerably. In other words, in a range in which the inclination of the voltage relative to the charge amount in the open circuit voltage characteristic V in each of the cell blocks B1 and B2 is large, the current flowing through each of the cell blocks B1 and B2 may vary considerably. Therefore, a large current may flow in one of the cell blocks B1 and B2, and the current load of one of the cell blocks B1 and B2 may increase.


In a state where no current flows through the battery module 2, the voltage characteristic of the battery module 2 (the relation of the voltage to the charge amount or the SOC) is assumed to be the same as the open circuit voltage characteristic (the relation of the open circuit voltage to the charge amount or the SOC) of each of the cell blocks B1 to Bn. As described above, in the range in which the inclination of the voltage relative to the charge amount in the open circuit voltage characteristic V of each of the cell blocks B1 to Bn varies considerably, the current flowing through each of the cell blocks B1 to Bn may vary considerably. Therefore, in the range in which the inclination of the voltage relative to the charge amount in the open circuit voltage characteristic V of the battery module 2 varies considerably, the current flowing through each of the cell blocks B1 to Bn may vary considerably. That is, in a range in which a secondary differential value at the charge amount of the open circuit voltage of the battery module 2 is large, the current flowing through each of the cell blocks B1 to Bn may vary considerably.


With a model of the battery module 2 including the two cell blocks B1 and B2 that are different from each other in capacity and the internal resistance, calculation was actually performed. In the model used in the calculation, the capacity, such as the charge capacity, is smaller and the internal resistance is higher in the cell block B1 than in the cell block B2. Thus, the degree of deterioration in the cell block B1 is higher than in the cell block B2. As a result, the relation of the open circuit voltage V1 relative to the SOC (open circuit voltage characteristic) in the cell block B1 is set as indicated by the solid line in FIG. 3A. The relation of the open circuit voltage V2 relative to the SOC (open circuit voltage characteristic) in the cell block B2 is set as indicated by the broken line in FIG. 3A. Furthermore, by adjusting the current I flowing through the battery module 2, the relation of the voltage Vc relative to the SOC (voltage characteristic) in the battery module 2 is set as indicated by the dot chain line in FIG. 3A. In FIG. 3A, the abscissa line represents the SOC and the ordinate line represents the voltage.


In the calculation, if the open circuit voltages V1 and V2 and the voltage Vc were set as described above, the current i1 flowing through the cell block B1 and the current i2 flowing through the cell block B2 were calculated. In addition, the current load P1 of the cell block B1 and the current load P2 of the cell block B2 were calculated. Then, the relationship between the SOC and each of the currents i1 and i2 were calculated as shown in FIG. 3B, and the relationship between the SOC and each of the current loads P1 and P2 was calculated as shown in FIG. 3C. As the parameter Fk for use in calculation of the current load Pk (k is either 1 or 2), the charge capacity (the charge capacity of the SOC 0% to 100%) was used. In FIG. 3B, the abscissa axis represents the SOC and the ordinate axis represents the current. In FIG. 3B, a change in the current i1 relative to the SOC is indicated by the solid line, and a change in the current i2 relative to the SOC is indicated by the broken line. In FIG. 3C, the abscissa axis represents the SOC and the ordinate axis represents the current load. In FIG. 3C, a change in the current load P1 relative to the SOC is indicated by the solid line, and a change in the current load P2 relative to the SOC is indicated by the broken line.


As shown in FIG. 3A to FIG. 3C, if the SOC was at or around 70% and the SOC was at 90% or higher as a result of the calculation, the difference between the open circuit voltages V1 and V1 was large. If the SOC was either of at or around 70% and at 90% or higher, namely, if the SOC was within a predetermined range in which the difference between the open circuit voltages V1 and V1 was large, the currents i1 and i2 varied considerably. Therefore, if the SOC was within the predetermined range mentioned above, the current i1 of the cell block B1 having a smaller capacity and higher degree of deterioration became excessively large. On the other hand, if the SOC was out of the predetermined range mentioned above, namely, in most parts other than the predetermined range between the SOC 0% and the SOC 100%, the current i1 of the cell block B1 having a smaller capacity was smaller than the current i2 of the block B2.


If the SOC was out of the predetermined range mentioned above, namely, in most parts other than the predetermined range between the SOC 0% and the SOC 100%, the current load P1 of the cell block B1 was smaller than the current load P2 of the cell block B2, or there was substantially no difference between the current loads P1 and P2. On the other hand, if the SOC was either of at or around 70% and at 90% or higher, namely, if the SOC was within the predetermined range mentioned above, the current load P1 of the cell block B1 having a high degree of deterioration became excessively large, and variations of the current loads P1 and P2 become excessively large.


In this embodiment, the controller 12 controls charging and discharging of the battery module 2 based on the relationship of the current loads P1 to Pn of the cell blocks B1 to Bn relative to the SOC of the battery module 2. Then, the processor of the controller 12 acquires information indicative of the relationship of the current loads P1 to Pn of the cell blocks B1 to Bn relative to the SOC from the storage medium of the controller 12, or from a server connected to the controller 12 through a network. The information indicative of the relationship of the current loads P1 to Pn of the cell blocks B1 to Bn relative to the SOC of the battery module 2 includes a range of the SOC of the battery module 2 in which the current load (any of P1 to Pn) is liable to be high in a cell block (any of B1 to Bn) having a high degree of deterioration, namely, a range of the SOC of the battery module 2 in which the current loads P1 to Pn of the cell blocks B1 to Bn are liable to vary widely.


The controller 12 acquires the range of the SOC of the battery module 2 in which the current loads P1 to Pn of the cell blocks B1 to Bn are liable to vary widely as the predetermined range of the SOC of the battery module 2. Then, in each of the charge and the discharge of the battery module 2, if the SOC of the battery module 2 in real time is within the predetermined range mentioned above, the controller 12 suppresses the current I flowing through the battery module 2. Since the predetermined range of the SOC of the battery module 2 is the range of the SOC of the battery module 2 in which the current loads P1 to Pn of the cell blocks B1 to Bn are liable to vary widely, it corresponds to a range in which the inclination of the voltage relative to the charge amount in the open circuit voltage characteristic V of each of the cell blocks B1 to Bn changes considerably. In other words, the predetermined range of the SOC of the battery module 2 corresponds to a range in which the secondary differential value at the charge amount of the open circuit voltage in the open circuit voltage characteristic V of each of the cell blocks B1 to Bn is large. Therefore, the predetermined range of the SOC of the battery module 2 is set on the basis of the magnitude of a change in the inclination of the voltage relative to the charge amount in each of the cell blocks B1 to Bn.



FIG. 4 shows processing performed by the controller 12 (the current load determination unit 13 and the charge and discharge control unit 15) in the charge and discharge control of the battery module 2. The processing shown in FIG. 4 is periodically performed at predetermined timings in each of the charge and the discharge of the assembled battery 2. As shown in FIG. 4, in each of the charge and the discharge of the battery module 2, the current load determination unit 13 estimates and calculates a real time SOC of the battery module 2 (S101). As a result, the SOC of the battery module 2 is acquired as a parameter relating to the current loads P1 to Pn of the cell blocks B1 to Bn. The current load determination unit 13 calculates the SOC of the battery module 2 using measurement results of the current I and the voltage Vc. The method of calculating the SOC of the battery module 2 may be a current integration method, a calculation method using the relationship between the voltage Va and the SOC of the battery module 2, an estimation method using a Kalman filter, etc.


The current load determination unit 13 determines whether the calculated SOC of the battery module 2 is within the predetermined range of the SOC (S102). As described above, the predetermined range of the SOC corresponds to the range in which the inclination of the voltage relative to the charge amount in the open circuit voltage characteristic of the battery module 2 changes considerably. If the SOC of the battery module 2 is within the predetermined range, the current loads P1 to Pn of the cell blocks B1 to Bn are liable to vary widely.


In this embodiment, if the SOC of the battery module 2 is within the predetermined range, the current load determination unit 13 determines that the current loads P1 to Pn of the cell blocks B1 to Bn vary widely, namely, determines that the current loads P1 to Pn vary beyond a permissible range. On the other hand, if the SOC of the battery module 2 is out of the predetermined range, the current load determination unit 13 determines that variations of the current loads P1 to Pn of the cell blocks B1 to Bn are within the permissible range. In one example, if the SOC is either of at or around 70% and at 90% or higher, it is determined that the SOC of the battery module 2 is within the predetermined range.


If the SOC of the battery module 2 is within the predetermined range (S102—Yes), the charge and discharge control unit 15 suppresses the current I flowing through the battery module 2 (S103). The charge and discharge control unit 15 charges or discharges the battery module 2 under conditions in which the current I is suppressed (S104). On the other hand, if the SOC of the battery module 2 is out of the predetermined range (S102—No), the charge and discharge control unit 15 charges or discharges the battery module 2 without suppressing the current I (S104). Thus, based on the fact that the SOC of the battery module 2 is within the predetermined range, the charge and discharge control unit 15 suppresses the current I flowing through the battery module 2 as compared to the case in which the SOC of the battery module 2 is out of the predetermined range.


In this embodiment, the processing as described above is performed. Therefore, if the SOC of the battery module 2 enters the range in which the current load (any of P1 to Pn) is liable to be high in the cell block (any of B1 to Bn) having a high degree of deterioration, the current I flowing through the battery module 2 is suppressed. In other words, if the SOC of the battery module 2 enters the range in which the current loads P1 to Pn of the cell blocks B1 to Bn are liable to vary widely, the current I flowing through the battery module 2 is suppressed. Therefore, even if the SOC of the battery module 2 is within the predetermined range mentioned above, the current loads P1 to Pn are prevented from excessively varying between the cell blocks B1 to Bn. In addition, even if the cell blocks B1 to Bn vary in performance such as in the degree of deterioration, the current load (any of P1 to Pn) of the cell block (any of B1 to Bn) having a high degree of deterioration cannot be excessively high. Therefore, the increase in variations of deterioration between the cell blocks B1 to Bn is suppressed.


Second Embodiment


FIG. 5 shows a charge and discharge system 1 according to the second embodiment. In the following, explanations of elements similar to those of the first embodiment will be omitted. As shown in FIG. 5, in the present embodiment, the battery module 2 includes a plurality of current measurement units (current measurement circuits) X1 to Xn. The current measurement units X1 to Xn are electrically parallel to one another. A current measurement unit Xk (k is any one of 1 to n) is electrically connected to a cell block Bk in series, and detects and measures a current ik flowing through the cell block Bk. The controller 12 periodically acquires the measurement value of the currents i1 to in at predetermined timings. Accordingly, the change with time (time history) of each of the currents i1 to in is acquired by the controller 12.


In the present embodiment, the controller 12 integrates the current ik flowing through the cell block Bk, so that it can estimate the SOC of the cell block Bk and can also calculate a charge amount of the cell block Bk from the state of the SOC 0%. Thus, the controller 12 can estimate the SOC and the charge amount of each of the cell blocks B1 to Bn.


Furthermore, the current load determination unit 13 of the controller 12 estimates a parameter representing the internal state of the cell block Bk based on a measurement value and a change with time of the current ik, an estimation value of the charge amount of the cell block Bk, and a measurement value and a change with time of the voltage Vc of the battery module 2. At this time, as the parameter representing the internal state of the cell block Bk, either of a capacity (cell block capacity), such as charge capacity (full charge capacity) or a discharge capacity of the cell block Bk, and a positive electrode capacity or a negative electrode capacity of the cell block Bk is estimated. In one example, in the same manner as described in Reference Document 1 (Jpn. Pat. Appln. KOKAI Publication No. 2012-251806), the parameter representing the internal state of the cell block Bk is estimated. Accordingly, in the present embodiment, the parameter representing the internal state of each of the cell blocks B1 to Bk is estimated by the controller 12.


Furthermore, in the present embodiment, since the parameter representing the internal state of each of the cell blocks B1 to Bk is estimated as described above, the controller 12 can estimate a degree of deterioration of each of the cell blocks B1 to Bk based on the estimated parameter. In one example, the current load determination unit 13 of the controller 12 determines that the degree of deterioration of the cell blocks B1 to Bk becomes higher as the estimated charge capacity (full charge capacity) becomes smaller. Even by using the positive electrode capacity and the negative electrode capacity instead of the capacity such as the charge capacity, the degree of deterioration can be determined by the controller 12 in the same manner.


In the present embodiment, the current load determination unit 13 calculates a current load Pk of the cell block Bk. At this time, the measurement value of the current ik is used and the parameter representing the internal state of the cell block Bk is used as the parameter Fk. Then, the current load Pk is calculated as formula (6) described above. Thus, in the present embodiment, the current load determination unit 13 calculates the current loads P1 to Pn of the cell blocks B1 to Bn. In each of the charge and the discharge of the battery module 2, the charge and discharge control unit 15 of the controller 12 controls the current I flowing through the battery module 2 and controls the current flowing through each of the cell blocks B1 to Bn based on the calculated current loads P1 to Pn. Thus, the currents ia to in are controlled based on the calculated current loads P1 to Pn.



FIG. 6 shows processing performed in charge and discharge control of the battery module 2 by the controller 12 (the current load determination unit 13 and the charge and discharge control unit 15) according to the present embodiment. In this embodiment, as well as the first embodiment, the current load determination unit 13 performs the processing of S101 and S102. However, in this embodiment, the current load determination unit 13 calculates the current loads P1 to Pn of the cell blocks B1 to Bn from the measurement values of the currents i1 to in in the manner described above. If the SOC of the battery module 2 is within the predetermined range (S102—Yes), the current determination unit 13 determines whether there is a cell block in which the current load Pk is equal to or greater than a threshold Pth (S105).


If there is a cell block in which the current load Pk is equal to or greater than a threshold Pth, namely, if any one of the current loads P1 to Pn of the cell blocks B1 to Bn is equal to or greater than the threshold Pth (S105—Yes), the charge and discharge control unit 15 suppresses the current I flowing through the battery module 2 (S103). The charge and discharge control unit 15 charges or discharges the battery module 2 under conditions in which the current I is suppressed (S104). On the other hand, if all of the current loads P1 to Pn of the cell blocks B1 to Bn are smaller than the threshold Pth (S105—No), the charge and discharge control unit 15 charges or discharges the battery module 2 without suppressing the current I flowing through the battery module 2 (S104). The threshold value Pth is, for example, an upper limit of the permissible range of the current load, and stored in a storage medium of the controller 12, or a storage medium of a server connected to the controller 12 through a network.


As described above, according to the present embodiment, based on the fact that the SOC of the battery module 2 is within the predetermined range and that the current load of some of the cell blocks B1 to Bn is equal to or greater than the threshold value Pth, the current I flowing through the battery module 2 is suppressed. Thus, the current flowing through each of the cell blocks B1 to Bn is controlled based on the calculated current loads P1 to Pn. Furthermore, according to the present embodiment, based on the fact that the current load is equal to or greater than the threshold value Pth in some of the cell blocks B1 to Bn, the current flowing through the battery module 2 is suppressed as compared to the case in which the current load is smaller than the threshold value Pth in all of the cell blocks B1 to Bn. Thus, the current loads P1 to Pn of the cell blocks B1 to Bn are calculated more appropriately and the current I is controlled more appropriately based on the current loads P1 to Pn.


(Modifications of Second Embodiment)


In one modification of the second embodiment, the processing of S101 and S102 is not performed, and determination based on the SOC of the battery module 2 is not performed. However, in this modification, the determination of S105 based on the current loads P1 to Pa of the cell blocks B1 to Bn is performed by the current load determination unit 13 in the same manner as in the second embodiment. Also in this modification, if any one of the current loads P1 to Pn of the cell blocks B1 to Bn is equal to or greater than the threshold Pth (S105—Yes), the charge and discharge control unit 15 suppresses the current I flowing through the battery module 2 (S103). The charge and discharge control unit 15 charges or discharges the battery module 2 under conditions in which the current I is suppressed (S104). On the other hand, if all of the current loads P1 to Pn of the cell blocks B1 to Bn are smaller than the threshold Pth (S105—No), the charge and discharge control unit 15 charges or discharges the battery module 2 without suppressing the current I (S104).


In another modification of the second embodiment, the following processing may be performed instead of comparing each of the current loads P1 to Pn with the threshold value Pth in S105. In this modification, the current load determination unit 13 of the controller 12 determines a degree of deterioration of each of the cell blocks B1 to Bn based on either the full charge capacity or the positive electrode capacity and the negative electrode capacity. Here, a cell block Bε having the highest degree of deterioration of all cell blocks B1 to Bn is defined. In this modification, instead of the determination of S105, the current load determination section 13 compares the current load Pε of the cell block Bε with the current load of each of the cell blocks other than the cell block Bε.


If the current load Pε of the cell block Bε is equal to or greater than the current load of any of the cell blocks other than the cell block Bε, the charge and discharge control unit 15 suppresses the current I flowing through the battery module 2. The charge and discharge control unit 15 charges or discharges the battery module 2 under conditions in which the current I is suppressed. On the other hand, if the current load Pε of the cell block Bε is smaller than all of the current loads of the cell blocks other than the cell block Bε, the charge and discharge control unit 15 charges or discharges the battery module 2 without suppressing the current I flowing through the battery module 2.


It is assumed that the battery module 2 includes two cell blocks B1 and B2 (n=2), and the degree of deterioration of the cell block B1 is higher than that of the cell block B2. In this case, according to the present modification, the current load determination unit 13 compared the current loads P1 and P2. If the current load P1 is equal to or greater than the current load P2, the charge and discharge control unit 15 suppresses the current I flowing through the battery module 2. The charge and discharge control unit 15 charges or discharges the battery module 2 under conditions in which the current I is suppressed. On the other hand, if the current load P1 is smaller than the current load P2, the charge and discharge control unit 15 charges or discharges the battery module 2 without suppressing the current I flowing through the battery module 2.


Also in this modification, the current flowing through each of the cell blocks B1 to Bn is controlled based on the calculated current loads P1 to Pn in the same manner as in the second embodiment etc. Therefore, the present modification produces the same effects and advantages as those of the second embodiment etc.


Third Embodiment


FIG. 7 shows a charge and discharge system 1 according to the third embodiment. In the following, explanations of elements similar to those of the second embodiment will be omitted. Also in this embodiment, current measurement units (current measurement circuits) X1 to Xn are provided. The controller 12 acquires measurement values of currents i1 to in and a change with time (time history) of each of the currents i1 to in. Then, the current load determination unit 13 calculates the current loads P1 to Pn of the cell blocks B1 to Bn in the same manner as in the second embodiment.


In this embodiment, variable resistors Y1 to Yn are provided. The variable resistors Y1 to Yn are electrically parallel to one another. The variable resistors Yk (k is any one of 1 to n) are electrically connected to the cell block Bk in series. Thus, each of the variable resistors Y1 to Yn is connected in series to the corresponding one of the cell blocks B1 to Bn. In this embodiment, in the same manner as in the second embodiment, the charge and discharge control unit 15 of the controller 12 controls driving of the driving circuit 8, thereby controlling the current I flowing through the battery module 2. Furthermore, in this embodiment, the charge and discharge control unit 15 is configured to adjust resistance values r1 to rn of the variable resistors Y1 to Yn. The charge and discharge control unit 15 controls currents i1 to in by adjusting the resistance values r1 to rn.



FIG. 8 shows processing performed in charge and discharge control of the battery module 2 by the controller 12 (the current load determination unit 13 and the charge and discharge control unit 15) of the present embodiment. Also in this embodiment, in the same manner as in the second embodiment, the current load determination unit 13 performs the processing of S101, S102, and S105. If some of the current loads P1 to Pn of the cell blocks B1 to Bn is equal to or greater than the threshold value Pth (S105—Yes), the charge and discharge control unit 15 suppresses the current I flowing through the battery module 2 (S103).


If some of the current loads P1 to Pn of the cell blocks B1 to Bn is equal to or greater than the threshold value Pth (S105—Yes), the charge and discharge control unit 15 adjusts the resistance values r1 to rn of the variable resistors Y1 to Yn based on the current loads P1 to Pn of the cell blocks B1 to Bn (S106). Then, the charge and discharge control unit 15 charges and discharges the battery module 2 under conditions in which the current I is suppressed and the resistance values r1 to rn are adjusted (S104). On the other hand, if all of the current loads P1 to Pn of the cell blocks B1 to Bn are smaller than the threshold value Pth (S105—No), the charge and discharge control unit 15 charges or discharges the battery module 2 without either suppressing the current I flowing through the battery module 2 or adjusting the resistance values r1 to rn (S104).


In one example, the controller 12 adjusts the resistance values r1 to rn of the variable resistors Y1 to Yn in accordance with the magnitudes of the calculated current loads P1 to Pn. In this case, a variable resistor connected in series to a cell block having a large current load is set to a high resistance value, whereas a variable resistor connected in series to a cell block having a small current load is set to a low resistance value. As a result, an excessively large current is prevented from flowing through the cell block having a large current load. Thus, the resistance values r1 to rn are adjusted such that the variations of the current loads P1 to Pn are reduced.


In another example, the controller 12 calculates internal resistances R1 to Rn of the cell blocks B1 to Bn based on the currents i1 to in. The internal resistance Rk of the cell block Bk is expressed as formula (17) using the current ik. The charge and discharge control unit 15 performs a control so that the sum of the internal resistance Rk and the resistance value rk of the variable resistor Yk is equal in all cell blocks. In other words, the resistance values r1 to rn are adjusted to satisfy formula (18).










R
k

=




V
0



(

t
+

d

t


)


-


V
c



(
t
)






i
k



(

t
+

d

t


)


-


i
k



(
t
)








(
17
)








R
1

+

r
1


=



R
2

+

r
2


=


=


R
n

+

r
n








(
18
)







By adjusting the resistance values r1 to rn as described above, each of the currents i1 to in is controlled such that the variations of the currents i1 to in are reduced, namely, the currents i1 to in are the same or substantially the same as one another. Thus, the resistance values r1 to rn are adjusted such that the variations of the current loads P1 and Pn are reduced. If the resistance values r1 to rn are adjusted to satisfy formula (18), it is preferable that the resistance values r1 to rn be adjusted such that the sum of the resistance values r1 to rn of the variable resistors Y1 to Yn are as small as possible. The method of calculating the internal resistance Rk may be an estimation method using a Kalman filter, a calculation using a sequential least squares method, a calculation using Fourier transform, etc., in addition to the method using formula (17).


The present embodiment produces the same effects and advantages as those of the second embodiment etc. Furthermore, according to the present embodiment, it is not only the current I flowing through the battery module 2 that is adjustable, but also the currents i1 to in are adjustable by adjusting the resistance values r1 to rn of the variable resistors Y1 to Yn.


(Modifications of Third Embodiment)


Also in the case of providing the variable resistors Y1 to Yn as in the third embodiment, the processing by the controller 12 may be appropriately changed as in the modifications of the second embodiment described above.


In another modification, in the configuration in which the variable resistors Y1 to Yn are provided as in the third embodiment, the processing of suppressing the current I in S103 may not be performed. In this modification, if some of the current loads P1 to Pn of the cell blocks B1 to Bn is equal to or greater than the threshold value Pth (S105—Yes), the charge and discharge control unit 15 only adjusts the resistance values r1 to rn of the variable resistors Y1 to Yn in S106. In this modification also, the resistance values r1 to rn are adjusted in the same manner as in the third embodiment. Thus, the resistance values r1 to rn are adjusted such that the variations of the current loads P1 to Pn are reduced.


In at least one of the embodiments or examples described above, the current flowing through each of the cell blocks is controlled based on at least one of the current loads or a parameter relating to the current loads. Accordingly, in the battery module in which cell blocks are connected in parallel, the current loads are prevented from being excessively greatly varied between the cell blocks.


While certain embodiments have been described, these embodiments have been presented by way of example only, and are not intended to limit the scope of the inventions. Indeed, the novel embodiments described herein may be embodied in a variety of other forms; furthermore, various omissions, substitutions and changes in the form of the embodiments described herein may be made without departing from the spirit of the inventions. The accompanying claims and their equivalents are intended to cover such forms or modifications as would fall within the scope and spirit of the inventions.

Claims
  • 1. A charge and discharge control device that controls charging and discharging of a battery module in which a plurality of cell blocks, each including one or more unit cells, are connected in parallel to one another, the device comprising a controller configured to control a current flowing through each of the cell blocks based on at least one of a current load of each of the cell blocks or a parameter relating to the current load.
  • 2. The charge and discharge control device according to claim 1, wherein the controller is configured to: estimate a state of charge (SOC) of the battery module as the parameter relating to the current load, andsuppress a current flowing through the battery module, at least based on a fact that the SOC of the battery module is within a predetermined range, as compared to a case in which the SOC of the battery module is out of the predetermined range.
  • 3. The charge and discharge control device according to claim 2, wherein the predetermined range concerning the SOC of the battery module is set based on a magnitude of a change of inclination of a voltage relative to a charge amount in each of the cell blocks.
  • 4. The charge and discharge control device according to claim 2, wherein the controller is configured to: calculate the current load of each of the cell blocks using a measurement value of the current flowing through each of the cell blocks, andsuppress the current flowing through the battery module, based on a fact that the current load is equal to or greater than a threshold value in any of the cell blocks in addition to a fact that the SOC of the battery module is within the predetermined range.
  • 5. The charge and discharge control device according to claim 1, wherein the controller is configured to: calculate the current load of each of the cell blocks using a measurement value of the current flowing through each of the cell blocks, andcontrol the current flowing through each of the cell blocks based on the calculated current load.
  • 6. The charge and discharge control device according to claim 5, wherein the controller is configured to suppress a current flowing through the battery module, based on a fact that the current load is equal to or greater than a threshold value in any of the cell blocks, as compared to a case in which the current load is smaller than the threshold value in all of the cell blocks.
  • 7. The charge and discharge control device according to claim 5, wherein: a plurality of variable resistors parallel to one another are provided, each of the variable resistors being connected to a corresponding one of the cell blocks; andthe controller is configured to adjust a resistance value of each of the variable resistors based on the calculated current load, thereby controlling the current flowing through each of the cell blocks.
  • 8. A charge and discharge system comprising: the charge and discharge control device according to claim 1; andthe battery module, a charging and discharging of which is controlled by the charge and discharge control device.
  • 9. A charge and discharge control method of controlling charging and discharging of a battery module in which a plurality of cell blocks, each including one or more unit cells, are connected in parallel to one another, the method comprising controlling a current flowing through each of the cell blocks based on at least one of a current load of each of the cell blocks or a parameter relating to the current load.
  • 10. A non-transitory storage medium storing a charge and discharge control program for charging and discharging of a battery module in which a plurality of cell blocks, each including one or more unit cells, are connected in parallel to one another, the program causing a computer to control a current flowing through each of the cell blocks based on at least one of a current load of each of the cell blocks or a parameter relating to the current load.
Priority Claims (1)
Number Date Country Kind
2020-005970 Jan 2020 JP national