KR102005395B1 - Apparatus and method for counting battery cell connected in parallel - Google Patents

Abstract

The present invention relates to an apparatus and method for verifying the parallel connection of battery cells constituting a battery module and the number of battery cells connected in parallel based on a voltage drop and an internal resistance value generated in a balancing process.

Description

[0001] APPARATUS AND METHOD FOR COUNTING BATTERY CELL CONNECTED IN PARALLEL [0002]

The present invention relates to an apparatus and method for verifying the parallel connection of battery cells constituting a battery module and the number of battery cells connected in parallel based on a voltage drop and an internal resistance value generated in a balancing process.

R & D on energy storage systems is being actively pursued as an appropriate alternative to solve the problems such as the shortage of power supply and demand repeated every year. The energy storage system is a system that stores the generated power in the grid and increases the energy efficiency by supplying the power when necessary. As a battery-based energy storage system technology, lithium-ion batteries are attracting the most attention due to their high efficiency, high performance and excellent charge / discharge characteristics.

When the batteries are connected in parallel in order to increase the use time of such batteries, the BMS can not automatically recognize them, and the number of parallel-connected batteries must be directly inputted to the BMS by the user.

Accordingly, the present invention proposes an apparatus and method for verifying whether a battery is connected in parallel and the number of batteries connected in parallel.

The present invention provides an apparatus and method for measuring the voltage drop and the internal resistance of a battery cell during a balancing process to check whether the other battery cells are connected in parallel to the battery cell and how many battery cells are connected in parallel.

A method for confirming whether or not parallel connection of battery cells having the same battery output voltage and internal resistance value of the battery according to the embodiment of the present invention and the number of battery cells connected in parallel is performed, A reference cell voltage drop value setting step for setting a cell voltage drop value, a module voltage drop value measurement for measuring a voltage drop value generated in the battery module when a battery module composed of one battery cell or two or more battery cells connected in parallel is balanced A voltage drop value comparison step of comparing the measured module voltage drop value with the reference cell voltage drop value in the step of measuring the module voltage drop value, Parallel connection to determine whether parallel connections and the number of parallel-connected battery cells And a determination result recognition step of recognizing the results of the number determination step and the parallel connection and number determination step in the BMS.

The reference cell voltage drop value setting step sets the balancing voltage drop value generated in one battery cell when the battery cell constituting the battery module is one, And may be set as a reference value for determining the number of battery cells connected in parallel.

The voltage drop value comparing step compares the voltage drop value generated in the single cell and the voltage drop value generated in the battery module to calculate a voltage drop value generated in the module and a cell voltage drop value generated in the single cell In the same case, a zero signal is generated, and a low signal can be generated when the voltage drop value generated in the module is smaller than the voltage drop value generated in the single cell.

The parallel connection and the number determination step may include determining that the battery module is configured as a single battery cell when a zero signal is generated in the voltage drop value comparison step and if a low signal is generated in the voltage drop value comparison step, The module determines that two or more battery cells are connected in parallel and the result of dividing the voltage drop value occurring in a single cell by the voltage drop value generated by the module may be the number of battery cells connected in parallel.

The step of recognizing the determination result may further include a step of calculating a SOC estimation and a battery balancing time of the battery module by recognizing the result of the parallel connection and the number determination step in the BMS.

A method for checking the parallel connection of the battery cells having the same battery output voltage and the battery internal resistance value and the number of parallel-connected battery cells according to another embodiment of the present invention includes: A module internal resistance value measuring step of measuring a combined internal resistance value of the battery module as a whole composed of one battery cell or two or more battery cells connected in parallel, The method comprising the steps of: comparing the total internal resistance value of the battery cell with the internal resistance value of the reference cell; comparing the internal resistance value of the battery cell with the internal resistance value of the battery cell; Determining parallel connection and number, determining the number of parallel connection and number determination The can comprise the determination result in the recognition step of recognizing BMS.

The reference internal resistance value setting step sets a reference value for determining whether the battery cells constituting the battery module are connected in parallel or the number of parallel-connected battery cells, by setting the internal resistance value of one battery cell .

Comparing the internal resistance value of the reference cell with the combined internal resistance value of the battery module to determine whether the combined internal resistance value of the battery module and the reference cell internal resistance value are equal to each other, And generates a low signal when the combined internal resistance value of the battery module is smaller than the internal resistance value of the reference cell.

Wherein the parallel connection and number determination step determines that the battery module is composed of a single battery cell when a zero signal is generated in the internal resistance value comparison step and when a low signal is generated in the voltage drop value comparison step, The module may determine that two or more battery cells are connected in parallel and the result of dividing the internal resistance value of the single cell by the combined internal resistance value of the battery module may be the number of the battery cells connected in parallel.

The step of recognizing the determination result may further include a step of calculating a SOC estimation and a battery balancing time of the battery module by recognizing the result of the parallel connection and the number determination step in the BMS.

The apparatus for verifying whether or not parallel connection of battery cells having the same battery output voltage and internal resistance value of the battery and the number of parallel-connected battery cells according to the embodiment of the present invention confirms the voltage drop value A module voltage drop value measuring unit for measuring a voltage drop value of the module, which is a voltage drop value generated in the battery module, when the battery module composed of one memory or two or more battery cells is balanced, A voltage drop value comparing unit for comparing the generated voltage drop value and the module voltage drop value in a single cell stored in the memory cell array, and determining the number of parallel connected battery cells and the parallel connection of the battery cells from the result of the voltage drop value comparing unit A parallel connection and a number determination unit.

The memory cell stores a reference cell voltage drop value generated in one battery cell when the battery cell constituting the battery module is one, and the reference cell voltage drop value is determined by the voltage drop value comparison unit And the number of parallel-connected battery cells may be a reference value.

The voltage drop value comparing unit compares the voltage drop value generated in the single cell with the voltage drop value generated in the battery module and if the voltage drop value generated in the module is equal to the cell voltage drop value generated in the single cell Generates a zero signal, and generates a low signal when the voltage drop value generated by the module is smaller than a voltage drop value generated in the single cell.

The parallel connection and number determination unit determines that the battery module is composed of a single battery cell when a zero signal is generated in the voltage drop value comparison unit and when a low signal is generated in the voltage drop value comparison unit, The result of dividing the voltage drop value generated in the single cell by the voltage drop value generated in the module may be the number of the battery cells connected in parallel.

The apparatus for verifying the parallel connection of the battery cells having the same battery output voltage and the internal resistance value of the battery and the number of parallel-connected battery cells according to another embodiment of the present invention includes: A module internal internal resistance value measuring unit for measuring a combined internal resistance value of a battery module composed of one or more battery cells, a memory for storing a value, a reference internal resistance value stored in the memory, An internal resistance value comparing unit for comparing the combined internal resistance value, and a parallel connection and number determining unit for determining whether the battery cells are connected in parallel or the number of parallel connected battery cells from the result of the internal resistance value comparing unit.

The internal resistance value of one battery cell is stored in the memory, and the internal resistance value of the reference cell is determined by determining whether the battery cells constituting the battery module are connected in parallel or the number of battery cells connected in parallel May be a reference value.

The internal resistance value comparing unit compares the internal resistance value of the reference cell with the combined internal resistance value of the battery module and generates a zero signal when the combined internal resistance value of the battery module is equal to the internal resistance value of the reference cell A low signal can be generated when the combined internal resistance value of the battery module is smaller than the internal resistance value of the reference cell.

The parallel connection and number determination unit determines that the battery module is composed of a single battery cell when a zero signal is generated in the internal resistance value comparison unit and when a low signal is generated in the internal resistance value comparison unit, The result of dividing the internal resistance value of the reference cell by the combined internal resistance value of the battery module may be the number of the battery cells connected in parallel.

The present invention can confirm the presence or absence of the battery cells connected in parallel to the battery cell and the number of the battery cells connected in parallel by measuring the voltage drop value and the internal resistance value of the battery cell.

1 is a flowchart according to an embodiment of the present invention.
2 is a flowchart according to another embodiment of the present invention.
3 is a configuration diagram according to an embodiment of the present invention.
4 is a configuration diagram according to another embodiment of the present invention.

Hereinafter, exemplary embodiments according to the present invention will be described in detail with reference to the contents described in the accompanying drawings. However, the present invention is not limited to or limited by the exemplary embodiments. Like reference numerals in the drawings denote members performing substantially the same function.

Terms including ordinals, such as first, second, etc., may be used to describe various elements, but the elements are not limited to these terms. The terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, the first component may be referred to as a second component, and similarly, the second component may also be referred to as a first component. The terminology used in this application is used only to describe a specific embodiment and is not intended to limit the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments. Also, in certain cases, there may be a term selected arbitrarily by the applicant, in which case the meaning thereof will be described in detail in the description of the corresponding invention. Therefore, the term used in the present invention should be defined based on the meaning of the term, not on the name of a simple term, but on the entire contents of the present invention.

When an element is referred to as "including" an element throughout the specification, it is to be understood that the element may include other elements as well, without departing from the spirit or scope of the present invention.

1 is a flowchart according to an embodiment of the present invention.

A method for confirming whether or not parallel connection of battery cells having the same battery output voltage and internal resistance value of the battery according to the embodiment of the present invention and the number of battery cells connected in parallel is performed, A reference cell voltage drop value setting step (S110) for setting a cell voltage drop value, a module voltage measuring step of measuring a voltage drop value generated in the battery module when a battery module composed of one battery cell or two or more battery cells connected in parallel is balanced A voltage drop value comparing step (S130) for comparing the measured module voltage drop value with the reference cell voltage drop value measured in the module voltage drop value measuring step (S120), a drop value measuring step (S120) (S130), it is determined whether or not the battery cells constituting the battery module are connected in parallel and the number of parallel-connected battery cells And a determination result recognition step of recognizing the results of the parallel connection and number determination step S140 and the parallel connection and number determination step S140 in the BMS.

More specifically, the reference cell voltage drop value setting step S110 sets a balancing voltage drop value generated in one battery cell when one battery cell constituting the battery module is one, May be used as a reference value for determining whether the battery cells constituting the battery module are connected in parallel or the number of parallel-connected battery cells.

Meanwhile, the module voltage drop value measuring step (S120) may measure the voltage drop of one or more of the battery cells constituting the battery module.

The voltage drop value comparison step (S130) compares the voltage drop value generated in the single cell with the voltage drop value generated in the battery module, and compares the voltage drop value generated in the module with the voltage drop value generated in the single cell A zero signal is generated when the cell voltage drop value is the same and a low signal is generated when the voltage drop value generated by the module is smaller than the voltage drop value generated in the single cell.

As a concrete example, in a balancing circuit in which a voltage drop of 0.5 V occurs in a battery cell when only one battery cell is balanced, a voltage drop of 0.5 V occurs in one battery cell to generate a zero signal, When the battery module is connected to the balancing circuit, the resistance value for forcibly discharging the battery module does not change, but the internal resistance of the battery module is reduced by half compared with the case of balancing only one battery cell, and only a voltage drop of 0.25 V occurs, Signal can be generated.

If it is determined that the battery module is composed of a single battery cell when a zero signal is generated in the voltage drop value comparison step S130, the parallel connection and number determination step S140 may include comparing the voltage drop value S130), the battery module determines that two or more battery cells are connected in parallel, and determines that a voltage drop value generated in a single cell is divided into a voltage drop value generated in the module, Can be confirmed.

Meanwhile, the step of recognizing the determination result (S150) may further include a step of calculating the SOC estimation and the battery balancing time of the battery module by recognizing the result of the parallel connection and the number determination step in the BMS.

2 is a flow chart of another embodiment of the present invention.

A method for checking the parallel connection of the battery cells having the same battery output voltage and the battery internal resistance value and the number of parallel-connected battery cells according to another embodiment of the present invention includes: A module internal resistance value measuring step S220 for measuring a combined internal resistance value of the whole battery module constituted by one battery cell or two or more battery cells connected in parallel, (S230) for comparing the combined internal resistance value of the entire module measured in the measuring step with the reference internal resistance value of the module, A parallel connection and number determination step S240 for determining whether or not the cells are connected in parallel and the number of parallel-connected battery cells, And a determination result recognition step (S250) of recognizing the result of the number determination step (S240) in the BMS.

The reference internal resistance value setting step S210 sets an internal resistance value of one battery cell and sets a reference value for determining whether the battery cells constituting the battery module are connected in parallel or the number of battery cells connected in parallel .

The internal resistance value comparison step S230 compares the reference internal resistance value of the battery module with the combined internal resistance value of the battery module. When the combined internal resistance value of the battery module is equal to the reference internal resistance value of the battery module, and generates a low signal when the combined internal resistance value of the battery module is smaller than the internal resistance value of the reference cell.

In a concrete example, when one internal resistance value of the battery cell is 10 m OMEGA, the internal resistance is measured as 10 mΩ in one battery cell to generate a zero signal, and a battery module in which two battery cells are connected in parallel is connected to the balancing circuit , The combined internal resistance of the battery module can be measured to a value that is reduced by half to 5 mΩ to generate a low signal.

Meanwhile, in the parallel connection and number determination step S240, when a zero signal is generated in the internal resistance value comparison step S230, it is determined that the battery module is composed of a single battery cell, and the voltage drop value comparison step S230 ), The battery module determines that two or more battery cells are connected in parallel, and the result of dividing the internal resistance value of the single cell by the combined internal resistance value of the battery module is the number of the battery cells connected in parallel Can be confirmed.

Meanwhile, the step of recognizing the determination result (S250) may further include a step of calculating a SOC estimation and a battery balancing time of the battery module by recognizing the result of the parallel connection and the number determination step in the BMS.

3 is a configuration diagram according to an embodiment of the present invention.

The apparatus for verifying the parallel connection of the battery cells having the same battery output voltage and the internal resistance value of the battery and the number of the parallel-connected battery cells according to the embodiment of the present invention is a voltage drop value generated in the battery cell when the battery cells are balanced A memory 110 for storing a reference cell voltage drop value, and a module voltage drop value measuring unit 120 for measuring a voltage drop value of a voltage drop occurring in the battery module when the battery module composed of one or two or more battery cells is balanced A voltage drop value comparator 130 for comparing the generated voltage drop value with the module voltage drop value in a single cell stored in the memory, And a parallel connection and number determination unit 140 for determining the number of parallel connected cells and the number of parallel connected battery cells. have.

The reference cell voltage drop value generated in one battery cell is stored in the memory 110 when the battery cell constituting the battery module is one and the reference cell voltage drop value is stored in the voltage drop value comparator 130 Can be used as a reference value for determining whether the battery cells constituting the battery module are connected in parallel or the number of parallel-connected battery cells.

The voltage drop value comparator 130 compares a voltage drop value generated in the single cell with a voltage drop value generated in the battery module and compares a voltage drop value generated in the module with a voltage drop value generated in the single cell, A zero signal is generated if the drop value is the same and a low signal is generated when the voltage drop value generated in the module is smaller than the voltage drop value generated in the single cell.

The parallel connection and number determination unit 140 determines that the battery module is composed of a single battery cell when the voltage drop value comparator 130 generates a zero signal, The battery module determines that two or more battery cells are connected in parallel and the result of dividing the voltage drop value generated in the single cell by the voltage drop value generated in the module is the number of the battery cells connected in parallel Can be confirmed.

4 is a configuration diagram according to another embodiment of the present invention.

The apparatus for verifying the parallel connection of the battery cells having the same battery output voltage and the internal resistance value of the battery and the number of parallel-connected battery cells according to another embodiment of the present invention includes: A module internal resistance value measuring unit 220 for measuring a combined internal resistance value of a battery module composed of one or more battery cells, a memory 210 for storing a value of a reference cell internal resistance, And an internal resistance value comparing unit 230 for comparing a value of the internal resistance of the battery module with a combined internal resistance of the battery module, And a determination unit 240 may be included.

The internal resistance value of one battery cell is stored in the memory 210. The internal resistance value of the reference cell is determined by the internal resistance value comparing unit 230 whether the battery cells constituting the battery module are connected in parallel, It can be used as a reference value for determining the number of battery cells.

The internal resistance value comparator 230 compares the reference internal resistance value of the battery module with the combined internal resistance value of the battery module. If the combined internal resistance value of the battery module is equal to the internal resistance value of the reference cell, and generates a low signal when the combined internal resistance value of the battery module is smaller than the internal resistance value of the reference cell.

The parallel connection and number determination unit 240 determines that the battery module is composed of a single battery cell when the internal resistance value comparison unit 230 generates a zero signal and the internal resistance value comparison unit 230 The battery module determines that two or more battery cells are connected in parallel and determines the number of battery cells to which the result of dividing the internal resistance value of the reference cell by the combined internal resistance value of the battery module is connected in parallel have.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention.

110: Memory
120: Module voltage drop measuring part
130: Voltage drop comparison section
140: Parallel connection and number determination unit
220: Composite internal resistance measuring part of battery module
230: Internal resistance comparison unit

Claims (18)

A method for verifying whether or not parallel connection of battery cells having the same battery output voltage and internal resistance value of a battery and the number of battery cells connected in parallel,
A reference cell voltage drop value setting step of setting a reference cell voltage drop value which is a voltage drop value occurring in a single cell when the battery cells are balanced;
A module voltage drop value measuring step of measuring a voltage drop value generated in the battery module when the battery module composed of one battery cell or two or more battery cells connected in parallel is balanced;
A voltage drop value comparison step of comparing the measured module voltage drop value with the reference cell voltage drop value in the step of measuring the module voltage drop value;
A parallel connection and number determination step of determining whether the battery cells constituting the battery module are connected in parallel and the number of parallel-connected battery cells according to a result of the voltage drop value comparison step;
A determination result recognition step of recognizing a result of the parallel connection and the number determination step in the BMS;
And,
As a result of the determination,
Calculating a SOC estimation and a battery balancing time of the battery module by recognizing the result of the parallel connection and the number determination step in the BMS;
And determining the number of parallel connections of the battery cell.
The method according to claim 1,
The reference cell voltage drop value setting step may include:
A balancing voltage drop value generated in one battery cell is set when a battery cell constituting the battery module is set, and a reference value for determining whether the battery cells constituting the battery module are connected in parallel and the number of parallel- Wherein the number of parallel connections of the battery cells is set to a predetermined value.
The method according to claim 1,
The voltage drop value comparison step may include:
A voltage drop value generated in the single cell is compared with a voltage drop value generated in the battery module,
Generates a zero signal when a voltage drop value generated in the module is equal to a cell voltage drop value generated in the single cell,
And generating a low signal when a voltage drop value generated in the module is smaller than a voltage drop value generated in the single cell.
The method of claim 3,
The parallel connection and number determination step
When a zero signal is generated in the voltage drop value comparison step, it is determined that the battery module is composed of a single battery cell,
When a low signal is generated in the voltage drop value comparison step, the battery module determines that two or more battery cells are connected in parallel,
Wherein the result of dividing the voltage drop value occurring in the single cell by the voltage drop value generated in the module is the number of battery cells connected in parallel.
delete A method for verifying whether or not parallel connection of battery cells having the same battery output voltage and internal resistance value of a battery and the number of battery cells connected in parallel,
A reference cell internal resistance value setting step of setting an internal resistance value of a single battery cell;
A module synthesis internal resistance value measuring step of measuring a combined internal resistance value of a whole battery module constituted by one battery cell or two or more battery cells connected in parallel;
An internal resistance value comparison step of comparing the combined internal resistance value of the entire module measured at the module combined internal resistance value measuring step with the reference cell internal resistance value;
A parallel connection and number determination step of determining whether the battery cells constituting the battery module are connected in parallel and the number of parallel-connected battery cells according to a result of the internal resistance value comparison step;
A determination result recognition step of recognizing a result of the parallel connection and the number determination step in the BMS;
And,
As a result of the determination,
Calculating a SOC estimation and a battery balancing time of the battery module by recognizing the result of the parallel connection and the number determination step in the BMS;
And determining the number of parallel connections of the battery cell.
The method of claim 6,
The reference cell internal resistance value setting step may include:
Wherein a reference value for determining whether the battery cells constituting the battery module are connected in parallel and the number of parallel-connected battery cells is set by setting an internal resistance value of one battery cell.
The method of claim 6,
The internal resistance value comparison step may include:
The internal resistance value of the reference cell is compared with the combined internal resistance value of the battery module,
Generating a zero signal when the combined internal resistance value of the battery module is equal to the internal resistance value of the reference cell,
And generating a low signal when the combined internal resistance value of the battery module is smaller than the internal resistance value of the reference cell.
The method of claim 8,
The parallel connection and number determination step
When a zero signal is generated in the internal resistance value comparison step, it is determined that the battery module is composed of a single battery cell,
When a low signal is generated in the internal resistance value comparison step, the battery module determines that two or more battery cells are connected in parallel,
Wherein the result of dividing the internal resistance value of the single cell by the combined internal resistance value of the battery module is the number of the battery cells connected in parallel.
delete An apparatus for verifying whether or not parallel connection of battery cells having the same battery output voltage and internal resistance value of a battery and the number of battery cells connected in parallel,
A memory for storing a reference cell voltage drop value, which is a voltage drop value generated in the battery cell when the battery cell is balanced;
A module voltage drop value measuring unit for measuring a voltage drop value of the module, which is a voltage drop value generated in the battery module, when the battery module composed of one or more battery cells is balanced;
A voltage drop value comparing unit for comparing the generated voltage drop value and the module voltage drop value in a single cell stored in the memory;
A parallel connection and number determination unit for determining from the result of the voltage drop value comparison unit whether the battery cells are connected in parallel and the number of parallel connected battery cells; And
BMS;
And,
The BMS,
Wherein the SOC estimation and the battery balancing time of the battery module are calculated according to whether the parallel connection of the battery cells is determined by the parallel connection and number determination unit and the number of parallel connected battery cells.
The method of claim 11,
The memory
The reference cell voltage drop value generated in one battery cell is stored when the battery cell constituting the battery module is one, and the reference cell voltage drop value is stored in the battery cell And a reference value for determining the number of parallel-connected battery cells and the number of parallel-connected battery cells.
The method of claim 11,
The voltage drop value comparing unit
A voltage drop value generated in the single cell is compared with a voltage drop value generated in the battery module,
Generates a zero signal if a voltage drop value generated in the module is equal to a cell voltage drop value generated in the single cell,
And generates a low signal when a voltage drop value generated by the module is smaller than a voltage drop value generated in the single cell.
14. The method of claim 13,
The parallel connection and number determination unit
When the voltage drop value comparator generates a zero signal, it determines that the battery module is composed of a single battery cell,
When the voltage drop value comparator generates a low signal, the battery module determines that two or more battery cells are connected in parallel,
Wherein the result of dividing the voltage drop value occurring in the single cell by the voltage drop value generated in the module is the number of battery cells connected in parallel.
An apparatus for verifying whether or not parallel connection of battery cells having the same battery output voltage and internal resistance value of a battery and the number of battery cells connected in parallel,
A memory in which a reference cell internal resistance value, which is an internal resistance value of a single battery cell, is stored;
A module synthesis internal resistance value measuring unit for measuring a combined internal resistance value of a battery module constituted by one or more battery cells;
An internal resistance value comparing unit for comparing a reference internal resistance value stored in the memory with a combined internal resistance value of the battery module;
A parallel connection and number determination unit for determining from the result of the internal resistance value comparison unit whether the battery cells are connected in parallel and the number of parallel connected battery cells; And
BMS;
And,
The BMS,
Wherein the SOC estimation and the battery balancing time of the battery module are calculated according to whether the parallel connection of the battery cells is determined by the parallel connection and number determination unit and the number of parallel connected battery cells.
16. The method of claim 15,
The memory
The internal resistance value of one battery cell is stored and the internal resistance value of the reference cell is a reference value for determining whether the battery cells constituting the battery module are connected in parallel or the number of parallel- Characterized by the number of parallel connections of the battery cell.
16. The method of claim 15,
The internal resistance value comparing unit
The internal resistance value of the reference cell is compared with the combined internal resistance value of the battery module,
Generates a zero signal if the combined internal resistance value of the battery module is equal to the internal resistance value of the reference cell,
And generates a low signal when the combined internal resistance value of the battery module is smaller than the internal resistance value of the reference cell.
18. The method of claim 17,
The parallel connection and number determination unit
When a zero signal is generated in the internal resistance value comparing unit, it is determined that the battery module is composed of a single battery cell,
When a low signal is generated in the internal resistance value comparing unit, the battery module determines that two or more battery cells are connected in parallel,
Wherein the result of dividing the internal resistance value of the reference cell by the combined internal resistance value of the battery module is the number of battery cells connected in parallel.

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