JP2021087266A - Power storage device and power storage module - Google Patents

Abstract

To provide a power storage device and a power storage module capable of balancing voltages of cell batteries without increasing arithmetic load.SOLUTION: A power storage device 1 comprises: a power storage module 3 having a plurality of cell batteries C1 to CM connected in series, and a wiring part 30 having a plurality of wires L0 to LM for detecting respective voltages of the plurality of cell batteries; and a voltage monitoring module 2 having a balancing circuit 20 which can selectively discharge each of the plurality of cell batteries, and a controller 22 that detects the respective voltages of the plurality of cell batteries on the basis of signals in the plurality of wires and makes the balance circuit execute discharge of a cell battery selected by the balancing circuit so as to suppress variations in the voltages of the plurality of cell batteries. The wiring part is configured so that a total resistance of the wires is equal to a first resistance value fo each of the plurality of cell batteries.SELECTED DRAWING: Figure 1

Description

The present disclosure relates to a power storage device and a power storage module.

Conventionally, a voltage monitoring module that monitors the voltage of an assembled battery has been known. The assembled battery may be a power storage module having a plurality of cell batteries connected in series and using, for example, a secondary battery as the cell battery. When the voltage balance of the cell battery is lost, the voltage monitoring module restores the voltage balance by, for example, discharging at least one cell battery. When discharging the cell battery, the device described in Patent Document 1 determines the discharge voltage by correcting it with a correction coefficient obtained from the internal resistance value of the cell battery, the wiring resistance value, the bypass resistance value of the bypass resistor, and the like. To do.

Japanese Unexamined Patent Publication No. 2016-80478

However, for example, the wiring resistance value differs for each cell battery. Therefore, in the apparatus described in Patent Document 1, it is necessary to obtain the correction coefficient for each cell battery, which imposes a heavy calculation burden.

An object of the present disclosure made in view of such a point is to provide a power storage device and a power storage module capable of maintaining the voltage balance of a cell battery without increasing the calculation load.

The power storage device according to an embodiment of the present disclosure is a power storage module including a plurality of cell batteries connected in series and a wiring unit having a plurality of wires for detecting the voltage of each of the plurality of cell batteries. And a balance circuit capable of selectively discharging each of the plurality of cell batteries, and detecting the voltage of each of the plurality of cell batteries based on the signals of the plurality of wirings, and the plurality of cell batteries. A voltage monitoring module including a controller for executing the discharge of the cell battery selected by the balance circuit so as to suppress the fluctuation of the voltage of the above. The wiring unit is configured such that the total resistance of the wiring is the first resistance value for each of the plurality of cell batteries.

The power storage module according to the embodiment of the present disclosure includes a plurality of cell batteries connected in series, a wiring unit having a plurality of wires for causing the voltage monitoring module to detect the respective voltages of the plurality of cell batteries, and a wiring unit. To be equipped. The wiring unit is configured such that the total resistance of the wiring is the first resistance value for each of the plurality of cell batteries.

According to one embodiment of the present disclosure, it is possible to provide a power storage device and a power storage module capable of maintaining the voltage balance of the cell battery without increasing the calculation load.

FIG. 1 is a diagram showing a configuration example of a power storage device according to an embodiment of the present disclosure. FIG. 2 is a diagram showing a configuration example of a balance circuit and a wiring portion. FIG. 3 is a diagram showing an example of a wiring pattern of the wiring portion. FIG. 4 is a diagram illustrating the influence of the resistance of the wiring portion during the operation of the balance circuit. FIG. 5 is a diagram showing the resistance distribution of the wiring portion. FIG. 6 is a flowchart showing a control method of the voltage monitoring module. FIG. 7 is a diagram showing a resistance distribution of the wiring portion of the comparative example.

(Configuration of power storage device)
As shown in FIG. 1, the power storage device 1 of one embodiment is a device that supplies electric power to a load of an electronic device or the like, and includes a voltage monitoring module 2 and a power storage module 3. The voltage monitoring module 2 includes a balance circuit 20, a storage 21, and a controller 22. The controller 22 includes a voltage detection unit 220 and a switch control unit 221. Storage module 3 includes a plurality of cell batteries _C 1 -C _M, and the wiring portion 30 having a plurality of wirings _L 0 ~L _M, the. M is an integer greater than or equal to 2. Cell batteries _{C N-1,} the cell battery _{C N} and cell batteries _{C N + 1} is part of a plurality of cell batteries _C 1 -C _M. The wiring _{L N-2,} the wiring _{L N-1,} the wiring _{L N} and the wiring _{L N + 1} is a part of the wiring _L 0 ~L _M. However, when N is 1, the cell battery _CN-1 and the wiring L _N-2 are omitted. When N is M, the cell battery _{CN + 1} and the wiring L _{N + 1} are omitted. FIG. 1 is an example. The power storage device 1 does not have to include all of the components shown in FIG. Further, the power storage device 1 may include components other than those shown in FIG.

The power storage module 3 is a module that stores electric power and supplies the stored electric power to a load. Storage module 3 includes a plurality of cell batteries C ₁ -C _M connected in series. In the present embodiment, a plurality of cell batteries C ₁ -C _M secondary battery, stored electric power is charged at an appropriate timing so within a predetermined range.

Wiring section 30 includes a plurality of wirings _L 0 ~L _M for detecting the voltage of each of the plurality of cell batteries _C 1 -C _M. A plurality of wirings _L 0 ~L _M are connected to respective terminals and the voltage monitoring module 2 of a plurality of cell batteries _C 1 -C _M. For example wiring L _N is connected to the second terminal of the cell batteries C _{N + 1} of the first terminal and the cell batteries C _N. For example wiring _{L N-1} is connected to the first terminal and the second terminal of the cell batteries _{C N-1} of the cell batteries _{C N.} The first terminal is, for example, a negative electrode terminal. The second terminal is, for example, a positive electrode terminal.

The voltage monitoring module 2 monitors and manages the voltage of the power storage module 3. Specifically, the voltage monitoring module 2 monitors the voltage in the unit of cell batteries C _N, suppresses variations in the plurality of cell batteries C ₁ -C _M voltage.

Balance circuit 20 is a circuit capable of selectively discharging each of the plurality of cell batteries C ₁ -C _M. Balance circuit 20 by discharging the cell batteries C _N higher than other voltage, so that voltage balance multiple cell batteries C ₁ -C _M is maintained. The specific configuration of the balance circuit 20 will be described later.

The storage 21 stores programs and data as a storage unit. The storage 21 temporarily stores the processing result of the controller 22. The storage 21 may include any storage device such as a semiconductor storage device, an optical storage device and a magnetic storage device. The semiconductor storage device may include, for example, a semiconductor memory. The storage 21 may include a plurality of types of storage devices. The storage 21 may include a combination of a portable storage medium such as a memory card and a reading device for the storage medium. The program stored in the storage 21 includes a program that causes the controller 22 to function as a voltage detection unit 220 and a switch control unit 221.

The controller 22 is, for example, a processor such as a CPU (Central Processing Unit). The controller 22 may be an integrated circuit such as a SoC (System-on-a-Chip) in which other components are integrated. The controller 22 may be configured by combining a plurality of integrated circuits. The controller 22 comprehensively controls the operation of the power storage device 1 to realize various functions. Specifically, the controller 22 refers to the data stored in the storage 21 as needed. The controller 22 executes instructions included in the program stored in the storage 21 to realize various functions. In the present embodiment, the controller 22 realizes the functions of the voltage detection unit 220 and the switch control unit 221 by executing the instruction of the program read from the storage 21.

Voltage detecting unit 220 detects the voltage of each of the plurality of cell batteries _C 1 -C _M based on the signals of a plurality of lines _L 0 ~L _M. Voltage detecting unit 220, when the voltage of the cell batteries C _N is higher than the other, to determine the cell batteries C _N and the discharge target may output the determination result to the switch controller 221. Further, the voltage detection unit 220 _{corrects the cell battery CN} and the adjacent cell batteries _{CN-1, CN + 1} discharged by the balance circuit 20 with a value based on the first resistance value described later.

The switch control unit 221, so as to suppress the variation in the plurality of cell batteries C ₁ -C _M voltage, the balance circuit 20 to execute the discharge of the cell batteries C _N of a discharge target. Specifically, switch control unit 221, the cell batteries C _N selected by the determination of the voltage detection unit 220, to discharge by controlling the switch having balanced circuit 20.

FIG. 2 is a diagram showing a configuration example of the balance circuit 20 and the wiring unit 30. In this embodiment, the balance circuit 20 includes a discharge circuit having a switch and a resistor. Balance circuit 20 comprises a discharge circuit for each of a plurality of cell batteries _C 1 -C _M. In the example of FIG. 2, the switch is a MOSFET, but the switch is not limited thereto. The gate of the MOSFET of each discharge circuit is controlled by the controller 22, and the MOSFET is switched on or off. For example MOSFET gate discharge circuit of the cell batteries _{C N} is connected to the SW (N) terminal of the controller 22. In the example of FIG. 2, when the high level signal is outputted from the SW (N) terminal of the controller 22, MOSFET of the discharge circuit of the cell batteries C _N it is turned on. Further, when the low level signal is outputted from the SW (N) terminal of the controller 22, MOSFET of the discharge circuit of the cell batteries _{C N} are turned off.

Further, for example, the drain of the MOSFET of the discharge circuit of the cell batteries _{C N} is connected to the wiring _{L N} electrically. The drain of the MOSFET of the discharge circuit of the cell batteries _{C N} is also connected via a resistor to the source of the MOSFET of the discharge circuit of the cell batteries _{C N + 1.} Source of the MOSFET of the discharge circuit of the cell batteries _{C N} are wired _{L N-1} electrically connected through a resistor. When the MOSFET of the discharge circuit of the cell batteries _{C N} is turned on, the drain - current Q0 between the source (see FIG. 4) flows. That, MOSFET of the discharge circuit of the cell batteries C _N is turned on, and the cell batteries C _N is discharged, it is possible to lower the voltage of the cell battery C _N.

Each wire of the wiring portion 30 has a connecting portion TVs to be connected to the part of the terminals of the cell batteries C ₁ -C _M at one end. Further, the other end of each wiring of the wiring portion 30 is connected to the connector. The connection connector is a component that constitutes a connection port to which the connection cable from the voltage monitoring module 2 is connected. Each wiring of the wiring unit 30 is electrically connected to the controller 22 of the voltage monitoring module 2. For example, the wiring L _N is connected to the Vs (N) terminal of the controller 22 through the balance circuit 20. Which is one end connecting portion TVs wiring _{L N} (N) is connected to the second terminal of the cell batteries _{C N + 1} of the first terminal and the cell batteries _{C N.} Further, for example, the wiring L _N-1 is connected to the Vs (N-1) terminal of the controller 22 through the balance circuit 20. Wiring _{L N-1} is one end connecting portion TVs (N-1) is connected to the first terminal and the second terminal of the cell batteries _{C N-1} of the cell batteries _{C N.}

FIG. 3 is a diagram showing an example of a wiring pattern of the wiring unit 30. In the present embodiment, since the densely arranged cell batteries C ₁ -C _M, connecting portion TVs are disposed on the top and bottom alternately. For example, the connecting portion TVs (N-2) are arranged at the upper part, and the connecting portion TVs (N-1) are arranged at the lower part. Then, the connecting portion TVs (N) are arranged at the upper part, and the connecting portion TVs (N + 1) are arranged at the lower part. As shown in the example of FIG. 3, due to the recent demand for miniaturization, the lengths of the plurality of wirings in the wiring portion 30 are usually different. For example, it is difficult to use an equal-length wiring pattern because it leads to an increase in the size of the power storage module 3.

(correction)
FIG. 4 is a diagram illustrating the influence of the resistance of the wiring portion 30 during the operation of the balance circuit 20. When the balance circuit 20 is in operation, it means that the discharge circuit is in the ON state. The controller 22, as described above, is connected to a plurality of wirings L ₀ ~L _M, acquires the signal. Here, signals of a plurality of lines _L 0 ~L _M is the voltage at the first or second terminals of the plurality of cell batteries _C 1 -C _M. Voltage detecting unit 220 of the controller 22, when the discharge circuit detects the voltage of the cell batteries C _N in the OFF state, it is only determines the difference between the voltage and the wiring L _N-1 voltage wiring L _N.

If the discharge circuit detects the voltage of the cell batteries C _N in the ON state, the wiring L _N of the resistance value P1, the deviation based on the wiring L _N-1 of the resistance value P2 and flowing through the discharge circuit current Q0 occurs. For example, when the voltage of the cell batteries C _N which discharge is performed is adjusted to 3.6V, when the voltage detecting unit 220 obtains a difference between the voltage and the wiring L _N-1 of the voltage of the wiring L _N, The calculated value is 3.6-P1 × Q0-P2 × Q0 [V]. Moreover, the cell batteries _{C N + 1} of the adjacent, the voltage of the cell battery _{C N + 1} is a 3.6V, a value which is calculated in the same manner as described above will be 3.6 + P1 × Q0 [V] . Moreover, the cell batteries _{C N-1} adjacent, the voltage of the cell battery _{C N-1} is a 3.6V, a value which is calculated in the same manner as described above will be 3.6 + P2 × Q0 [V] . Therefore, when the discharge cell battery _{C N} executed exists, the voltage detection unit 220, it is necessary to correct cell batteries _{C N,} the _{C N-1} and _{C N + 1.}

Here, if the resistance of the wiring L ₀ ~L _M, for example, randomly different, since the voltage detecting unit 220 that it is necessary to obtain the respective resistance of the wiring L ₀ ~L _M individually calculated, the calculation amount of correction Increase. To suppress the calculation amount of the correction of the voltage detection unit 220, it is necessary not to cause individual variations in the value of resistance of the wiring L ₀ ~L _M.

FIG. 5 is a diagram showing a resistance distribution of the wiring portion 30 of the power storage device 1 of the present embodiment. The vertical axis shows the resistance value. The number on the horizontal axis corresponds to the subscript of the wiring _L 0 ~L _M or cell batteries _C 1 -C _M. In the example of FIG. 5 M corresponding to the total number of cell batteries _C 1 -C _M is 48. In the present embodiment, the total resistance of the wiring of the cell batteries C _N is designed to be the first resistance value. Here, the total resistance of the wiring of the cell batteries C _N were combined with the resistance value of the wiring L _N-1 of the first terminal of the cell batteries C _N, and the resistance value of the wiring L _N of the second terminal, the The value. The wiring L _N has a second resistance value when N is an odd number and a third resistance value when N is an even number. Further, the wiring L _N-1 has a third resistance value when N is an odd number and a second resistance value when N is an even number. Regardless of the value of _N , the total resistance of the wiring of the cell battery CN is the sum of the second resistance value and the third resistance value, that is, the first resistance value.

Here, the resistance distribution in FIG. 5 corresponds to the wiring pattern shown in FIG. In the present embodiment, the width of each wiring is adjusted so that _{the wiring L N} when N is an odd number has a second resistance value. Further, the width of each wiring is adjusted so that _{the wiring L N} when N is an even number has a third resistance value. Thus, the wiring portion 30, by the width of each of the plurality of wirings L ₀ ~L _M is adjusted for each of a plurality of cell batteries C ₁ -C _M, the total resistance of the wiring is first resistor It is configured to be a value.

Because the total resistance of the wiring for each of the plurality of cell batteries C ₁ -C _M is the first resistance value, the voltage detection unit 220 of the controller 22, discharge circuit detects the voltage of the cell batteries C _N ON state In some cases, the value based on the first resistance value can be easily corrected. According to the example of FIG. 4, the voltage detection unit 220, the wiring _{L N} of the resistance value P1, the wiring _{L N-1} of but based on the resistance value P2 and current Q0 can be corrected, the resistance value P1 and the resistance value P2 Since the sum is the known first resistance value, it does not need to be calculated. Further, as the current Q0, a known current value defined in the design of the discharge circuit is used. Therefore, the voltage detection unit 220, it is possible to easily correct the voltage of the cell battery C _N.

Further, as described above, the correction needs to be performed for the cell batteries C _N-1 and C _{N + 1} is connected to the cell batteries C _N of executing the discharge. Here, according to the example of FIG. 4, the voltage detection unit 220 can correct the voltage _{of the cell battery CN + 1} based on the resistance value P1 and the current Q0 of the _{wiring L N.} Further, the voltage detection unit 220 _{can correct the voltage of the cell battery CN-1} based on the resistance value P2 and the current Q0 of the wiring L _N-1. Here, the sum of the resistance value P1 and the resistance value P2 is a known first resistance value. Further, the resistance value P1 is one of the second resistance value and the third resistance value, and the resistance value P2 is the other. Therefore, if the relationship between the second resistance value and the third resistance value is known to the first resistance value, the voltage detection unit 220 can easily use the voltage of the cell batteries _CN-1 and _{CN + 1} . Can be corrected. Here, the relationship with the first resistance value refers to a mathematical formula or the like capable of calculating a second resistance value or a third resistance value from the first resistance value, for example, a ratio. The ratio of the second resistance value or the third resistance value to the first resistance value is determined and known, for example, in the design of the wiring pattern shown in FIG. Therefore, the voltage detection unit 220 can easily correct the voltages of the _{cell battery CN + 1} and the cell battery _CN-1.

(flowchart)
FIG. 6 is a flowchart showing a control method of the voltage monitoring module 2. Controller 22 of the voltage monitoring module 2 by executing the control according to this flowchart, it is possible to maintain the voltage balance in the plurality of cell batteries C ₁ -C _M of battery modules 3.

The controller 22 detects the voltages of the cell batteries _C 1 -C _M (step S1). If all the discharge circuit of the cell batteries C ₁ -C _M is off, the voltage detecting unit 220 of the controller 22, by determining the voltage difference between adjacent lines, it is possible to detect the voltage.

The controller 22 detects a high voltage cell battery (step S2). Voltage detecting unit 220 of the controller 22, when the voltage of the cell batteries C _N is higher than the other, to determine the cell batteries C _N and the discharge target may output the determination result to the switch controller 221. Here, the state higher than the other voltage, may be at higher that than a predetermined voltage than the reference value of the cell batteries C ₁ -C _M. The reference value is, for example, 3.6V. The predetermined voltage is, for example, 0.1 V.

The controller 22 executes switch control (step S3). Switch controller of the controller 22 221 may output a control signal to the balance circuit 20, to the switch of the discharge circuit of the selected cell cell C _N as the discharge target ON state. When the discharge circuit of the cell batteries C _N is turned on, the cell battery C _N is discharged, the voltage of the cell batteries C _N is lowered.

The controller 22 executes the correction process (step S4). The switch control unit 221 of the controller 22 may store information that can be used in the correction in the storage 21 as the correction process. Information that may be used in correction, such as the discharge is, information of executed cell batteries C _N. Specific examples of the discharge information of executed cell batteries C _N is a numerical value of N.

The controller 22 detects the voltages of the cell batteries _C 1 -C _M, to confirm that a uniform balanced (step S5). Voltage detecting unit 220 of the controller 22, like step S1, detects the voltages of the cell batteries _C 1 -C _M. At this time, the voltage detection unit 220 of the controller 22 executes the correction for the cell batteries C _{N-1, C N + 1} of discharge of the cell batteries _{C N} and adjacent been executed. Voltage detection unit 220, the discharge and is executed cell batteries C _N information, first resistance value used in calculating the value of the current Q0, and the second resistance value or the third resistance value and a first Information such as the relational expression with the resistance value is acquired from the storage 21. The controller 22 performs the above correction calculation based on this information. The controller 22 confirms that the balance of the plurality of cell batteries C ₁ -C _M of voltage after the correction are aligned, the series of processing is terminated. Here, the controller 22 may further execute the following processing and then end the series of processing. The voltage detection unit 220 of the controller 22 may output a signal indicating that the balance is achieved to the switch control unit 221. Then, the switch controller 221, and can not execute the correction is more may delete the information of the cell batteries C _N which discharge is performed from the storage 21. The switch control unit 221 outputs a control signal to the balance circuit 20, the switch of the discharge circuit of the cell batteries C _N was discharged subject may then turned off.

(Comparison example)
FIG. 7 is a diagram showing a resistance distribution of the wiring portion 30 included in the power storage device 1 of the comparative example. The notation of the vertical axis and the horizontal axis is the same as that of FIG. 5, and the description thereof will be omitted. In the comparative example, the width of each of the plurality of wirings of the wiring portion 30 L ₀ ~L _M is not adjusted. Therefore, the resistance value in accordance with the respective lengths of the connector of the wiring L ₀ ~L _M to the connecting portion TVs are varied.

In the comparative example, the resistance value P1 and the wiring L _N-1 of the resistance value P2 of the wiring L _N in the example of FIG. 4 differs depending on the position of the cell batteries C _N to be detected. Therefore, the voltage detecting unit 220 of the controller 22, when the discharge circuit detects the voltage of the cell batteries C _N in the ON state, is corrected using a cell batteries C different resistance values for each position of the _N P1 and the resistance value P2 It is necessary, and the calculation load increases. Further, in the comparative example, since it is necessary to store the cell batteries C _N resistance value P1 and the resistance value P2 for each position in each storage 21 is increased, the size of the power storage device 1 of the comparative example as a result increases.

Power storage apparatus 1 according to this embodiment, the wiring portion 30 of the energy storage module 3 for each of the plurality of cell batteries C ₁ -C _M, the total resistance of the wiring is formed such that the first resistance value. Power storage apparatus 1 according to this embodiment, as apparent in comparison with Comparative Example, it is possible to maintain the voltage balance of the cell batteries C ₁ -C _M without increasing the calculation load.

Although the embodiments have been described above based on the drawings and examples, it should be noted that those skilled in the art can easily make various modifications and modifications based on the present disclosure. It should be noted, therefore, that these modifications and modifications are within the scope of this disclosure. For example, the functions included in each member, each means, each step, etc. can be rearranged so as not to be logically inconsistent, and a plurality of means and / or steps, etc. can be combined or divided into one. It is possible.

The above embodiment is not limited to the embodiment as the power storage device 1. For example, the above embodiment may be implemented as a method executed by a device such as the power storage device 1.

For example, in the above embodiment, as shown in FIG. 1, the power storage device 1 has been described as one device. However, the power storage device 1 of the present disclosure is not limited to one device, and may include a plurality of independent devices.

For example, the voltage monitoring module 2 of the power storage device 1 may include a communication device that communicates with a power conditioner that manages a plurality of power storage devices 1. Voltage monitoring module 2, a plurality of cell batteries C ₁ -C _M detected voltage for the energy storage module 3, the discharge target determined cell cell C _N, the information such as the state of the on-off switch having balanced circuit 20, It may be output to the power conditioner via a communication device.

For example, the voltage detection unit 220 may further perform temperature-based adjustment (hereinafter, temperature correction) in the correction. The temperature correction may be performed based on the temperature acquired from the temperature sensor provided in the power storage module 3. As another example, the temperature compensation may be performed based on the environmental temperature acquired from the temperature sensor provided in the housing of the power storage device 1. At this time, the temperature of at least a part of the first resistance value, the value of the current Q0, and the second resistance value or the relational expression between the third resistance value and the first resistance value used in the correction calculation. The correction may be performed. As an example, the current Q0 may be stored in the storage 21 as a function of temperature. In the correction, the voltage detection unit 220 may calculate the value of the current Q0 based on the temperature acquired from the temperature sensor.

For example, in the above embodiment, the second resistance value and the third resistance value are different, but the second resistance value and the third resistance value may be the same value. That is, the second resistance value and the third resistance value may be set to half the value of the first resistance value. At this time, the discharge can perform the correction of the cell batteries C _{N + 1} and cell batteries C _N-1 of the voltage adjacent to the cell battery C _N, which is performed by more simple calculation.

In the present disclosure, the descriptions such as "first" and "second" are identifiers for distinguishing the configuration. The configurations distinguished by the descriptions such as "first" and "second" in the present disclosure can exchange numbers in the configurations. The exchange of identifiers takes place at the same time. Even after exchanging identifiers, the configuration is distinguished. The identifier may be deleted. The configuration with the identifier removed is distinguished by a code. Based solely on the description of identifiers such as "first" and "second" in the present disclosure, it shall not be used as an interpretation of the order of the configurations or as a basis for the existence of identifiers with lower numbers.

The 17 international goals adopted at the United Nations Summit in September 2015 are the Sustainable Development Goals (SDGs). Among the 17 goals of the SDGs, the power storage device 1 and the power storage module 3 according to one embodiment are, for example, "7. Energy for everyone and clean", "9. Let's lay the foundation for industry and technological innovation", and It can contribute to the achievement of the goals of "11. Creating a town where people can continue to live".

1 Power storage device 2 Voltage monitoring module 3 Power storage module 20 Balance circuit 21 Storage 22 Controller 30 Wiring unit 220 Voltage detection unit 221 Switch control unit C ₁ , _CN-1 , _CN , _{CN + 1} , _CM cell battery L ₀ , L _{N-2, L N-1} , L N, L N + 1, L M wires

Claims (4)

A power storage module including a plurality of cell batteries connected in series and a wiring unit having a plurality of wirings for detecting the voltage of each of the plurality of cell batteries.
A balance circuit capable of selectively discharging each of the plurality of cell batteries, and a voltage of each of the plurality of cell batteries is detected based on signals of the plurality of wirings, and the voltages of the plurality of cell batteries are detected. A voltage monitoring module including a controller for executing discharge of the cell battery selected in the balance circuit so as to suppress variation in the voltage is provided.
The wiring unit is a power storage device configured such that the total resistance of the wiring is the first resistance value for each of the plurality of cell batteries. The power storage device according to claim 1, wherein the wiring portion is adjusted in width of each of the plurality of wirings. The power storage device according to claim 1 or 2, wherein the controller corrects by a value based on the first resistance value when detecting the voltage of the cell battery in which the discharge is executed. With multiple cell batteries connected in series,
The voltage monitoring module includes a wiring unit having a plurality of wirings for detecting the respective voltages of the plurality of cell batteries.
The wiring unit is a power storage module configured such that the total resistance of the wiring is the first resistance value for each of the plurality of cell batteries.

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