阅读说明：本技术 电池管理系统 (Battery management system ) 是由 李基瑛 闵庚春 于 2020-03-10 设计创作，主要内容包括：一种电池单体组件的电池管理系统,该电池单体组件包括多个单体,该电池管理系统包括：第一单体平衡电阻器和第一单体平衡开关,其被连接在单体当中的对应第一单体的正极和负极之间；以及,第二单体平衡电阻器和第二单体平衡开关,其被连接在第一单体的正极和负极之间,其中,在第一单体平衡开关的接通时段期间流动的第一单体平衡电流高于在第二单体平衡开关的接通时段期间流动的第二单体平衡电流。(A battery management system for a battery cell assembly, the battery cell assembly including a plurality of cells, the battery management system comprising: a first cell balancing resistor and a first cell balancing switch connected between the positive electrode and the negative electrode of a corresponding first cell among the cells; and a second cell balancing resistor and a second cell balancing switch connected between the positive electrode and the negative electrode of the first cell, wherein a first cell balancing current flowing during an on period of the first cell balancing switch is higher than a second cell balancing current flowing during an on period of the second cell balancing switch.)

1. A battery management system for a battery cell assembly, the battery cell assembly including a plurality of cells, the battery management system comprising:

a first cell balancing resistor and a first cell balancing switch connected between a positive electrode and a negative electrode of a corresponding first cell among the cells; and

a second cell balancing resistor and a second cell balancing switch connected between the positive electrode and the negative electrode of the first cell,

wherein a first cell balancing current flowing during an on period of the first cell balancing switch is higher than a second cell balancing current flowing during an on period of the second cell balancing switch.

2. The battery management system of claim 1, wherein the first cell balancing resistor comprises:

a first resistor connected between the positive pole of the first cell and the first terminal of the first cell balancing switch; and

a second resistor connected between the cathode of the first cell and the second end of the first cell balancing switch.

3. The battery management system of claim 1, wherein the second cell balancing resistor comprises:

a third resistor connected between the positive terminal of the first cell and the first terminal of the second cell balancing switch; and

a fourth resistor connected between the cathode of the first cell and the second end of the second cell balancing switch.

4. The battery management system of claim 1,

the first cell balancing switch and the second cell balancing switch are both turned on when a voltage difference between cells, which is a voltage difference between the first cell and at least one cell adjacent to the first cell, is higher than or equal to a first reference voltage.

5. The battery management system of claim 4,

the first cell balancing switch is turned on when a voltage difference between the cells is higher than or equal to a second reference voltage and lower than the first reference voltage.

6. The battery management system of claim 5,

the second cell balancing switch is turned on when the voltage difference between the cells is higher than or equal to a cell balancing threshold voltage and lower than the second reference voltage.

7. The battery management system of claim 1,

when the temperature of the first cell balancing resistor is higher than or equal to a reference temperature and the temperature of the second cell balancing resistor is lower than the reference temperature,

controlling cell balance of the first cell by using a second cell balance resistor.

8. The battery management system of claim 1,

when the temperature of the second cell balancing resistor is higher than or equal to a reference temperature and the temperature of the first cell balancing resistor is lower than the reference temperature,

controlling cell balance of the second cell by using a first cell balance resistor.

9. A battery management system for a battery cell assembly, the battery cell assembly including a plurality of cells, the battery management system comprising:

a cell monitoring IC configured to include a plurality of first cell balancing switches corresponding to the cells, the first cell balancing switches being connected to the cells through first cell balancing resistors;

a cell balancing IC configured to include a plurality of second cell balancing switches corresponding to the cells, the second cell balancing switches being connected to the cells through second cell balancing resistors;

a main control circuit configured to calculate a voltage difference between cells for each of the cells based on the received cell voltages of the cells, determine a cell balancing target cell depending on a result of comparing the voltage difference between the cells with a first reference voltage, a second reference voltage, and a cell balancing threshold voltage, and control a cell balancing operation by using at least one of the cell monitoring IC and the cell balancing IC depending on a comparison result; and

the voltage difference between the cells is a cell voltage of each of the cells and a voltage difference between at least one cell adjacent to each of the cells.

10. The battery management system of claim 9,

a first cell balancing current flowing through an on first cell balancing switch among the first cell balancing switches is greater than a second cell balancing current flowing through an on second cell balancing switch among the second cell balancing switches.

11. The battery management system of claim 10,

the main control circuit controls the cell monitoring IC and the cell balancing IC to turn on both of a first cell balancing switch and a second cell balancing switch connected to a cell having a voltage difference between cells higher than or equal to a first reference voltage among a plurality of voltage differences between the cells.

12. The battery management system of claim 11,

the main control circuit controls the cell monitoring IC and the cell balancing IC to turn on a first cell balancing switch connected to a cell having a voltage difference between cells higher than or equal to a second reference voltage and lower than the first reference voltage among voltage differences between the cells.

13. The battery management system of claim 12,

the main control circuit controls the cell monitoring IC and the cell balancing IC to turn on a second cell balancing switch connected to a cell having a voltage difference between cells higher than or equal to a cell balancing threshold voltage and lower than the second reference voltage among the voltage differences between the cells.

14. The battery management system of claim 9,

for a first cell connected to a first cell balancing resistor having a temperature equal to or higher than a reference temperature among the first cell balancing resistors, the main control circuit controls the cell monitoring IC and the cell balancing IC to perform cell balancing of the first cell by using a second cell balancing resistor connected to the first cell.

15. The battery management system of claim 9,

for a first cell connected to a second cell balancing resistor having a temperature equal to or higher than a reference temperature among the second cell balancing resistors, the main control circuit controls the cell monitoring IC and the cell balancing IC to perform cell balancing of the first cell by using a first cell balancing resistor connected to the first cell.

Technical Field

Cross Reference to Related Applications

This application claims priority and benefit from korean patent application No.10-2019-0056452 filed on 14.5.2019 with the korean intellectual property office, the entire contents of which are incorporated herein by reference.

The present disclosure relates to a battery management system, and more particularly, to a battery management system for cell balance control.

Background

A battery management system (hereinafter, referred to as "BMS"), which monitors the state of a battery and controls the charge and discharge of the battery, controls a cell balancing operation so as to similarly maintain the voltages of a plurality of cells constituting the battery. The voltage difference between the cells causes the cells to deteriorate, which affects their life span, and the deterioration of the cell having a cell voltage significantly different from that of another cell among the cells increases, and such a cell may cause overcharge.

Among cell balancing methods, the passive cell balancing method is a method of connecting a resistor to a cell having a large cell voltage difference from other cells to allow a current (hereinafter, referred to as "cell balancing current") to flow from the corresponding cell to the resistor. In this case, the cell balancing operation time may be reduced as the cell balancing current increases.

When cell balancing is performed using the cell monitoring ICs under the control of the conventional BMS, there is a limitation in reducing the time required for cell balancing since the cell balancing current is limited according to the function of the cell monitoring ICs.

Disclosure of Invention

[ problem ] to provide a method for producing a semiconductor device

The present invention has been made in an effort to provide a battery management system capable of adjusting cell balance currents and a battery device including the same.

[ technical solution ] A

An exemplary embodiment of the present invention provides a battery management system of a battery cell assembly including a plurality of cells, the battery management system including: a first cell balancing resistor and a first cell balancing switch connected between the positive electrode and the negative electrode of a corresponding first cell among the cells; and a second cell balancing resistor and a second cell balancing switch connected between the positive electrode and the negative electrode of the first cell. A first cell balancing current flowing during an on period of the first cell balancing switch may be higher than a second cell balancing current flowing during an on period of the second cell balancing switch.

The first cell balancing resistor may include: a first resistor connected between the anode of the first cell and the first terminal of the first cell balancing switch; and a second resistor connected between the cathode of the first cell and the second terminal of the first cell balancing switch.

The second cell balancing resistor may include: a third resistor connected between the anode of the first cell and the first terminal of the second cell balancing switch; and a fourth resistor connected between the cathode of the first cell and the second terminal of the second cell balancing switch.

The battery management system may turn on both the first cell balancing switch and the second cell balancing switch when a voltage difference between the cells, which is a voltage difference between the first cell and at least one cell adjacent to the first cell, is higher than or equal to a first reference voltage.

The battery management system may turn on the first cell balancing switch when the voltage difference between the cells is higher than or equal to the second reference voltage and lower than the first reference voltage.

The battery management system may turn on the second cell balancing switch when the voltage difference between the cells is higher than or equal to the cell balancing threshold voltage and lower than the second reference voltage.

The battery management system may control cell balance of the first cell by using the second cell balancing resistor when a temperature of the first cell balancing resistor is higher than or equal to a reference temperature and a temperature of the second cell balancing resistor is lower than the reference temperature.

The battery management system may control cell balance of the second cell by using the first cell balancing resistor when the temperature of the second cell balancing resistor is higher than or equal to the reference temperature and the temperature of the first cell balancing resistor is lower than the reference temperature.

Another exemplary embodiment of the present invention provides a battery management system of a battery cell assembly including a plurality of cells, including: a cell monitoring IC configured to include a plurality of first cell balancing switches corresponding to the cells, which are connected to the cells through first cell balancing resistors; a cell balancing IC configured to include a plurality of second cell balancing switches corresponding to the cells, which are connected to the cells through second cell balancing resistors; a main control circuit configured to calculate a voltage difference between the cells for each of the cells based on the received cell voltages of the cells, and determine a cell balancing target cell depending on a result of comparing the voltage difference between the cells with the first reference voltage, the second reference voltage, and the cell balancing threshold voltage, and control a cell balancing operation by using at least one of the cell monitoring IC and the cell balancing IC depending on the comparison result. The voltage difference between the cells may be a cell voltage of each of the cells and a voltage difference between at least one cell adjacent to each of the cells.

A first cell balancing current flowing through an on first cell balancing switch among the first cell balancing switches may be greater than a second cell balancing current flowing through an on second cell balancing switch among the second cell balancing switches.

The main control circuit may control the cell monitoring IC and the cell balancing IC to turn on both the first cell balancing switch and the second cell balancing switch connected to the cell having a voltage difference between cells higher than or equal to a first reference voltage among a plurality of voltage differences between cells.

The main control circuit may control the cell monitoring IC and the cell balancing IC to turn on a first cell balancing switch connected to a cell having a voltage difference between cells higher than or equal to a second reference voltage and lower than a first reference voltage among voltage differences between cells.

The main control circuit may control the cell monitoring IC and the cell balancing IC to turn on a second cell balancing switch connected to a cell having a voltage difference between cells higher than or equal to a cell balancing threshold voltage and lower than a second reference voltage among the voltage differences between cells.

For a first cell connected to a first cell balancing resistor having a temperature equal to or higher than a reference temperature among the first cell balancing resistors, the main control circuit may control the cell monitoring IC and the cell balancing IC to perform cell balancing of the first cell by using a second cell balancing resistor connected to the first cell.

For a first cell connected to a second cell balancing resistor having a temperature equal to or higher than a reference temperature among the second cell balancing resistors, the main control circuit may control the cell monitoring IC and the cell balancing IC to perform cell balancing of the first cell by using the first cell balancing resistor connected to the first cell.

[ PROBLEMS ] the present invention

It is possible to provide a battery management system and a battery device that can improve the accuracy of cell balancing by adjusting the cell balancing current and can shorten the cell balancing operation time.

Drawings

Fig. 1 illustrates a battery device according to an exemplary embodiment.

Fig. 2 illustrates a first connection circuit between a cell monitoring IC and a battery cell assembly according to an exemplary embodiment.

Fig. 3 illustrates a second connection circuit between the cell balancing IC and the battery cell assembly according to an exemplary embodiment.

Fig. 4 illustrates a partial configuration of a cell balancing IC according to an exemplary embodiment.

Fig. 5 illustrates a partial configuration of a cell monitoring IC according to an exemplary embodiment.

Fig. 6 illustrates a partial configuration showing a connection relationship between the cell monitoring IC and the battery cell assembly according to an exemplary embodiment.

Fig. 7 illustrates a partial configuration showing a connection relationship between the cell balancing IC and the battery cell assembly according to an exemplary embodiment.

FIG. 8 illustrates a flow chart showing a cell balancing control method dependent on a voltage difference between cells of a main control circuit according to an exemplary embodiment.

Fig. 9 illustrates a flowchart showing a cell balancing control method depending on the temperature of a cell balancing resistor of a main control circuit according to an exemplary embodiment.

Detailed Description

According to an exemplary embodiment of the present invention, the battery management system includes not only the cell monitoring IC but also the cell balancing IC, and the cell balancing IC supplies a cell balancing current (hereinafter, referred to as a "second cell balancing current") different from a cell balancing current (hereinafter, referred to as a "first cell balancing current") of the cell monitoring IC. When a voltage difference between one cell among the plurality of cells and another cell adjacent to the cell (hereinafter, referred to as "voltage difference between cells") is equal to or higher than a predetermined cell balancing threshold voltage, a cell balancing operation may be performed on a corresponding cell (hereinafter, referred to as a cell balancing target cell) depending on a comparison result with at least two reference voltages, i.e., a first reference voltage and a second reference voltage, by using at least one of the first cell balancing current and the second cell balancing current. The first cell equilibrium current may be greater than the second cell equilibrium current.

In this case, the cell balancing operation may be performed by using only one of the first cell balancing current and the second cell balancing current depending on the temperature of the resistor for cell balancing of the cell monitoring IC (hereinafter, referred to as a first cell balancing resistor) and the resistor for cell balancing of the cell balancing IC (hereinafter, referred to as a second cell balancing resistor) and the cell voltage difference.

Hereinafter, exemplary embodiments disclosed in the present specification will be described in detail with reference to the accompanying drawings. In this specification, the same or similar components will be denoted by the same or similar reference numerals, and a repetitive description thereof will be omitted. The terms "module" and/or "monomer" for components used in the following description are merely for ease of describing the present description. Thus, these terms do not have the meaning or effect of distinguishing them from themselves and from themselves to one another. In describing exemplary embodiments of the present specification, detailed descriptions of well-known technologies associated with the present invention are omitted when it is determined that they may make the gist of the present invention unclear. The drawings are provided only to allow easy understanding of exemplary embodiments disclosed in the specification and should not be construed as limiting the spirit disclosed in the specification, and it is to be understood that the present invention includes all modifications, equivalents, and alternatives without departing from the scope and spirit of the present invention.

Terms including ordinal numbers such as first, second, etc., will only be used to describe various components and should not be construed as limiting the components. These terms are only used to distinguish one component from another.

It will be understood that when a component is referred to as being "connected" or "coupled" to another component, it can be directly connected or coupled to the other component or can be connected or coupled to the other component through other components intervening therebetween. On the other hand, it is to be understood that when a component is referred to as being "directly connected or coupled" to another component, it can be connected or coupled to the other component without the intervening components therebetween.

It will be further understood that the terms "comprises" and "comprising," when used in this specification, specify the presence of stated features, integers, steps, operations, components, and/or groups thereof, but do not preclude the presence or addition of one or more other features, integers, steps, operations, components, and/or groups thereof.

Fig. 1 illustrates a battery device according to an exemplary embodiment.

As shown in fig. 1, the battery device 1 includes a battery cell assembly 2, a BMS 3, a relay 11, a shunt resistor 12, and a temperature sensor 13.

In the battery cell assembly 2, a plurality of battery cells are connected in series or in parallel to supply necessary electric power. In fig. 1, the battery Cell assembly 2 includes a plurality of battery cells 1 to Celln connected in series, and is connected between two output terminals OUT1 and OUT2 of the battery device 1, the relay 11 is connected between the positive electrode of the battery device 1 and the output terminal OUT1, and the shunt resistor 12 is connected between the negative electrode of the battery device 1 and the output terminal OUT 2. The constituent elements and the connection relationship between the constituent elements shown in fig. 1 are examples, and the present invention is not limited thereto.

The relay 11 controls the electrical connection between the battery device 1 and the load. When the relay 11 is turned on, the battery device 1 and the load are electrically connected to perform charging or discharging, and when the relay 11 is turned off, the battery device 1 and the load are electrically separated.

The shunt resistor 12 is connected in series to a current path between the battery cell assembly 2 and a load (not shown). The BMS 3 may measure a voltage across the shunt resistor 12 to calculate currents, i.e., a charging current and a discharging current, flowing through the battery cell assembly 2.

The temperature sensor 13 may be arranged at a predetermined position within the battery device 1, for example, in a region adjacent to the battery cell assembly 2, or may be physically coupled to the battery cell assembly 2. The temperature sensor 13 may detect the temperature of the location where it is disposed, and transmit information indicating the detected temperature to the BMS 3. Although not shown in fig. 1, at least two temperature sensors 13 may be provided to measure the temperature of each of the first cell balancing resistor and the second cell balancing resistor, or to provide temperature information to estimate the temperature of each of the first cell balancing resistor and the second cell balancing resistor. The first Cell balancing resistor is connected between the Cell monitoring IC10 and the cells Cell1 to Celln, and therefore, when Cell balancing is performed, a first Cell balancing current flows through the first Cell balancing resistor. The second Cell balancing resistor is connected between the Cell balancing IC 20 and the cells Cell1 to Celln, and therefore, when Cell balancing is performed, a second Cell balancing current flows through the second Cell balancing resistor.

The BMS 3 includes a first connection circuit 21, a second connection circuit 22, a cell monitoring IC10, a cell balancing IC 20, a main control circuit 30, and a relay driver 40.

The cell monitoring IC10 and the battery cell stack 2 may be electrically connected by a first connection circuit 21, and the cell balancing IC10 and the battery cell stack 2 may be electrically connected by a second connection circuit 22.

The cell monitoring IC10 may be electrically connected with each of the cells through the first connection circuit 21 to measure a cell voltage, and may measure a current flowing through the battery (hereinafter, referred to as "battery current") based on a voltage across the shunt resistor 12. Information on the battery current and the cell voltage measured by the cell monitoring IC10 is transmitted to the main control circuit 30 through the interface 23. The Cell monitoring IC 30 may discharge a Cell-balancing Cell among the cells Cell1 to Celln by using a first Cell-balancing resistor depending on a Cell-balancing control signal (hereinafter, referred to as a "first Cell-balancing control signal") transmitted from the main control circuit 30 through the interface 23.

The cell balancing IC 20 may be electrically connected with each of the cells through the second connection circuit 22 to measure the cell voltage, and may measure the battery current based on the voltage across the shunt resistor 12. Information about the cell current and the cell voltage measured by the cell balancing IC 20 is sent to the main control circuit 30 through the interface 24. The Cell balance IC 20 may discharge the Cell balance Cell among the cells Cell1 to Celln by using the second Cell balance resistor depending on the Cell balance control signal (hereinafter, referred to as "second Cell balance control signal") transmitted from the main control circuit 30 through the interface 24.

In addition, the cell monitoring IC10 and the cell balancing IC 20 may control a plurality of cell control operations required for the protection operation depending on the protection operation control signal transmitted from the main control circuit 30 through the corresponding interface 23 or 24. For example, the protection operation includes a protection operation for cell overvoltage, a protection operation for cell low voltage, a protection operation for short circuit, a protection operation for overcurrent, and the like.

The main control circuit 30 may receive a wake-up signal from the outside, for example, from an Electronic Control Unit (ECU)5 of the vehicle, to activate the cell balancing IC 20 and the cell monitoring IC10 in a sleep state. In addition, when an abnormal voltage equal to or higher than a certain level on the cell side is detected by at least one of the cell balancing IC 20 and the cell monitoring IC10, a wake-up signal may be transmitted to the main control circuit 30.

The main control circuit 30 may control the operation of the relay 11 based on the status information received from the cell monitoring IC10 and the cell balancing IC 20 through the interface 23 and the interface 24, respectively, and may control the cell balancing by controlling at least one of the cell monitoring IC10 and the cell balancing IC 20.

Specifically, the main control circuit 30 calculates a voltage difference between the cells for each of the cells based on the received Cell voltages of the cells Cell1 to Celln, determines a Cell balance target Cell depending on a result of comparing the voltage difference between the cells with the first reference voltage, the second reference voltage, and the Cell balance threshold voltage, and controls a Cell balancing operation by using at least one of the Cell monitoring IC10 and the Cell balancing IC 20 depending on the comparison result.

According to an exemplary embodiment, the voltage difference between the cells may be a difference between a Cell voltage of each Cell among the cells Cell1 to Celln and a Cell voltage of at least one Cell adjacent to each Cell. For example, at least one of the adjacent cells disposed above and below each cell may be an adjacent cell. In cell balancing, the voltage difference between two adjacent cells may be specified based on the low voltage cell.

When the voltage difference between the cells is equal to or higher than the first reference voltage, the main control circuit 30 may control the cell monitoring IC10 and the cell balancing IC 20 to turn on both the first cell balancing switch and the second cell balancing switch connected to the cell having the voltage difference between the cells equal to or higher than the first reference voltage. The main control circuit 30 may control the cell monitoring IC10 and the cell balancing IC 20 to turn on a first cell balancing switch connected to a cell having a voltage difference between cells equal to or higher than the second reference voltage and lower than the first reference voltage. The main control circuit 30 may control the cell monitoring IC10 and the cell balancing IC 20 to turn on a second cell balancing switch connected to a cell having a voltage difference between cells equal to or higher than a cell balancing threshold voltage and lower than a second reference voltage.

In addition, for a first cell connected to a first cell balancing resistor having a temperature equal to or higher than a reference temperature among the plurality of first cell balancing resistors, the main control circuit 30 may control the cell monitoring IC10 and the cell balancing IC 20 to perform cell balancing of the first cell by using a second cell balancing resistor connected to the first cell. In addition, for a first cell connected to a second cell balancing resistor having a temperature equal to or higher than a reference temperature among the plurality of second cell balancing resistors, the main control circuit 30 may control the cell monitoring IC10 and the cell balancing IC 20 to perform cell balancing of the first cell by using the first cell balancing resistor connected to the first cell.

Regarding cell balancing, the main control circuit 30 may transmit a first cell balancing control signal and a second cell balancing control signal to control the cell monitoring IC10 and the cell balancing IC 20.

In addition, when it is determined that an abnormal state such as a cell overvoltage, a cell undervoltage, a short circuit, or an overcurrent has occurred based on the state information, the main control circuit 30 may generate a protection operation control signal for driving a protection operation corresponding to the abnormal state that has occurred and transmit it to the cell monitoring IC10 and the cell balancing IC 20. The main control circuit 30 may transmit information about the battery device 1 through CAN communication with the ECU 5, and may receive instructions about the operation of the battery device 1 from the ECU to control the relay 11, the cell monitoring IC10, and the cell balancing IC 20.

The configuration of the battery device 1 according to the present exemplary embodiment has been described with reference to fig. 1, and each constituent element will be described later with reference to fig. 2 to 7.

Fig. 2 illustrates a first connection circuit between a cell monitoring IC and a battery cell assembly according to an exemplary embodiment.

In fig. 2, the battery Cell assembly 2 is shown to include eight Cell cells 1 through Cell8 connected in series, but the present invention is not limited thereto. In fig. 2, the first cell balancing resistor includes two cell balancing resistors RB1 and RB 2. Temperature sensor 13 may include a temperature sensor disposed adjacent to resistors RB1 and RB 2.

The first connection circuit 21 includes a plurality of resistors RC1 and RC2, a plurality of cell balancing resistors RB1 and RB2, and a plurality of capacitors C11 to C19 and C21 to C28. The cell monitoring IC10 includes a plurality of terminals VC0 to VC8 for cell voltage sensing and a plurality of terminals CB1H to CB8H and CB1L to CB8L for cell balancing.

In fig. 2, two resistors RC1 and RC2 are connected in series between the positive pole of cell Celli and terminal VCi. Alternatively, two resistors RC1 and RC2 are connected in series (i is one of natural numbers from 1 to 8) between the positive electrode of cell Celli and terminal VC (i-1).

Specifically, the terminal VC8 is connected to the positive electrode of the Cell8 through two resistors RC1 and RC 2. The terminal VC7 is connected to a node to which the cathode of the Cell8 and the anode of the Cell7 are connected through two resistors RC1 and RC 2. The terminal VC6 is connected to a node to which the cathode of the Cell7 and the anode of the Cell6 are connected through two resistors RC1 and RC 2. The terminal VC5 is connected to a node to which the cathode of the Cell6 and the anode of the Cell5 are connected through two resistors RC1 and RC 2. The terminal VC4 is connected to a node to which the cathode of the Cell5 and the anode of the Cell4 are connected through two resistors RC1 and RC 2. The terminal VC3 is connected to a node to which the cathode of the Cell4 and the anode of the Cell3 are connected through two resistors RC1 and RC 2. The terminal VC2 is connected to a node to which the cathode of the Cell3 and the anode of the Cell2 are connected through two resistors RC1 and RC 2. The terminal VC1 is connected to a node to which the cathode of the Cell2 and the anode of the Cell1 are connected through two resistors RC1 and RC 2. The terminal VC0 is connected to the cathode of the Cell1 through two resistors RC1 and RC 2.

In fig. 2, cell balancing resistor RB1 is connected between the positive electrode of cell Celli and terminal CBiH, and cell balancing resistor RB2 is connected in series between the negative terminal of cell Celli and terminal CBiL (i is one of natural numbers from 1 to 8).

Specifically, the terminal CB8H is connected to the positive pole of the Cell8 through the Cell balancing resistor RB1, and the terminal CB8L is connected to the negative pole of the Cell8 through the Cell balancing resistor RB 2. The terminal CB7H is connected to the positive pole of the Cell7 through a Cell balancing resistor RB1, and the terminal CB7L is connected to the negative pole of the Cell7 through a Cell balancing resistor RB 2. The terminal CB6H is connected to the positive pole of the Cell6 through a Cell balancing resistor RB1, and the terminal CB6L is connected to the negative pole of the Cell6 through a Cell balancing resistor RB 2. The terminal CB5H is connected to the positive pole of the Cell5 through a Cell balancing resistor RB1, and the terminal CB5L is connected to the negative pole of the Cell5 through a Cell balancing resistor RB 2. The terminal CB4H is connected to the positive pole of the Cell4 through a Cell balancing resistor RB1, and the terminal CB4L is connected to the negative pole of the Cell4 through a Cell balancing resistor RB 2. The terminal CB3H is connected to the positive pole of the Cell3 through a Cell balancing resistor RB1, and the terminal CB3L is connected to the negative pole of the Cell3 through a Cell balancing resistor RB 2. The terminal CB2H is connected to the positive pole of the Cell2 through a Cell balancing resistor RB1, and the terminal CB2L is connected to the negative pole of the Cell2 through a Cell balancing resistor RB 2. The terminal CB1H is connected to the positive pole of the Cell1 through a Cell balancing resistor RB1, and the terminal CB1H is connected to the negative pole of the Cell1 through a Cell balancing resistor RB 2.

Each of the capacitors C11 to C19 is formed between a connection node between the two corresponding resistors RC1 and RC2 and ground, and the capacitors C21 to C28 are formed between two corresponding terminals among the terminals VC0 to VC 8.

Fig. 3 illustrates a second connection circuit between the cell balancing IC and the battery cell assembly according to an exemplary embodiment.

In fig. 3, the battery Cell assembly 2 is shown to include the cells Cell1 to Cell8 connected in series, but the present invention is not limited thereto. In fig. 3, the second cell balancing resistor includes two cell balancing resistors RB3 and RB 4. The temperature sensor 13 may be arranged as a temperature sensor adjacent to the resistors RB3 and RB 4.

The second connection circuit 22 includes a plurality of resistors RC3 and RC4, a plurality of cell balancing resistors RB3 and RB4, and a plurality of capacitors C31 to C39 and C41 to C48. Cell balancing IC 20 includes a plurality of terminals vc 0-vc 8 for cell voltage sensing and a plurality of terminals cb1 h-cb 8h and cb1 l-cb 8l for cell balancing. In fig. 3, two resistors RC3 and RC4 are connected in series between the positive pole of cell Celli and terminal vci. Alternatively, two resistors RC3 and RC4 are connected in series (i is one of natural numbers from 1 to 8) between the negative pole of the cell Celli and the terminal vc (i-1).

Specifically, the terminal vc8 is connected to the positive pole of the Cell8 through two resistors RC3 and RC 4. The terminal vc7 is connected to a node to which the cathode of the Cell8 and the anode of the Cell7 are connected through two resistors RC3 and RC 4. The terminal vc6 is connected to a node to which the cathode of the Cell7 and the anode of the Cell6 are connected through two resistors RC3 and RC 4. The terminal vc5 is connected to a node to which the cathode of the Cell6 and the anode of the Cell5 are connected through two resistors RC3 and RC 4. The terminal vc4 is connected to a node to which the cathode of the Cell5 and the anode of the Cell4 are connected through two resistors RC3 and RC 4. The terminal vc3 is connected to a node to which the cathode of the Cell4 and the anode of the Cell3 are connected through two resistors RC3 and RC 4. The terminal vc2 is connected to a node to which the cathode of the Cell3 and the anode of the Cell2 are connected through two resistors RC3 and RC 4. The terminal vc1 is connected to a node to which the cathode of the Cell2 and the anode of the Cell1 are connected through two resistors RC3 and RC 4. The terminal vc0 is connected to the cathode of the Cell1 through two resistors RC3 and RC 4.

In fig. 3, the cell balance resistor RB3 is connected between the positive electrode of the cell Celli and the terminal chih, and the cell balance resistor RB2 is connected in series between the negative electrode of the cell Celli and the terminal cbil (i is one of natural numbers from 1 to 8).

Specifically, the terminal cb8h is connected to the positive pole of the Cell8 through the Cell balancing resistor RB3, and the terminal cb8l is connected to the negative pole of the Cell8 through the Cell balancing resistor RB 4. The terminal cb7h is connected to the positive pole of the Cell7 through a Cell balancing resistor RB3, and the terminal cb7l is connected to the negative pole of the Cell7 through a Cell balancing resistor RB 4. The terminal cb6h is connected to the positive pole of the Cell6 through a Cell balancing resistor RB3, and the terminal cb6l is connected to the negative pole of the Cell6 through a Cell balancing resistor RB 4. The terminal cb5h is connected to the positive pole of the Cell5 through a Cell balancing resistor RB3, and the terminal cb5l is connected to the negative pole of the Cell5 through a Cell balancing resistor RB 4. The terminal cb4h is connected to the positive pole of the Cell4 through a Cell balancing resistor RB3, and the terminal cb4l is connected to the negative pole of the Cell4 through a Cell balancing resistor RB 4. The terminal cb3h is connected to the positive pole of the Cell3 through a Cell balancing resistor RB3, and the terminal cb3l is connected to the negative pole of the Cell3 through a Cell balancing resistor RB 4. The terminal cb2h is connected to the positive pole of the Cell2 through a Cell balancing resistor RB3, and the terminal cb2l is connected to the negative pole of the Cell8 through a Cell balancing resistor RB 4. The terminal cb1h is connected to the positive pole of the Cell1 through a Cell balancing resistor RB3, and the terminal cb1h is connected to the negative pole of the Cell1 through a Cell balancing resistor RB 4.

Each of the capacitors C31 to C39 is formed between a connection node between the two corresponding resistors RC3 and RC4 and ground, and the capacitors C41 to C48 are formed between two corresponding terminals among the terminals vc0 to vc 8.

Fig. 4 illustrates a partial configuration of a cell balancing IC according to an exemplary embodiment.

The cell balancing IC 20 may include a plurality of cell balancing switches 101 to 108 and a cell balancing controller 100. Each of the cell balance switches 101 to 108 may be connected between two corresponding terminals, and may perform a switching operation depending on a corresponding gate signal.

The cell balance controller 100 turns on cell balance switches connected to the cell balance cells depending on the cell balance control signal received from the main control circuit 30. The on-period of the cell balancing switch may also depend on the cell balancing control signal.

Each 10i of the cell balance switches 101 to 108 may have a first terminal connected to the terminal cbih and a second terminal connected to the terminal cbil, and may perform a switching operation depending on the corresponding gate signal VGi. When the cell balance switch 10i is turned on, the cell Celli and the cell balance resistors RB3 and RB4 form a discharge path to discharge the cell Celli (i is one of natural numbers from 1 to 8).

The cell balance switches 101 to 108 and the cell balance controller 100 shown in fig. 4 may also be applied to the cell monitoring IC 10. In this case, the cell balance switches 101 to 108 and the cell balance controller 100 may also be applied to the terminals CB1H to CB8H and CB1L to CB8L instead of the terminals CB1h to CB8h and CB1l to CB8l shown in fig. 4.

Fig. 5 shows a partial configuration of a cell monitoring IC according to an exemplary embodiment.

The cell monitoring IC10 may include a cell voltage measurement circuit 200. The cell voltage measuring circuit 200 may measure a voltage between two adjacent terminals among the terminals VC8 to VC0 to transmit information indicating the measured cell voltage to the main control circuit 30 through the interface 23. The voltage between the terminal VCi and the terminal VC (i-1) is the cell voltage of the cell Celli (i is one of natural numbers from 1 to 8).

The cell voltage measurement circuit 200 shown in fig. 5 may also be applied to the cell balancing IC 20. In this case, the cell voltage measuring circuit 200 may be applied to the terminals CB1h to CB8h and CB1l to CB8l instead of the terminals CB1H to CB8H and CB1L to CB8L shown in fig. 5.

The connection relationship between the cell, the cell balancing resistor, and the cell balancing switch will be described in detail with reference to fig. 6 and 7.

Fig. 6 illustrates a partial configuration showing a connection relationship between the cell monitoring IC and the battery cell assembly according to an exemplary embodiment.

In fig. 6, a plurality of resistors RC1 and RC2, Cell balancing resistors RB1 and RB2, Cell balancing switch 305, Cell balancing controller 300, and Cell voltage measuring circuit 200 connected to Cell5 are illustrated.

The resistors RC1 and RC2 are connected in series between the positive electrode of the Cell5 and the terminal VC5, and the positive voltage of the Cell5 (or the negative voltage of the Cell 6) is transmitted to the Cell voltage measurement circuit 200 through the terminal VC 5. A resistor RB1 is connected between the positive pole of Cell5 and terminal CB5H, a first end of Cell balancing switch 305 is connected to terminal CB5H, a resistor RB2 is connected between the negative pole of Cell5 and terminal CB5L, and a second end of Cell balancing switch 305 is connected to terminal CB 5L. The cell balance switch 305 performs a switching operation depending on the gate signal VG5 supplied from the cell balance controller 300.

The resistors RC1 and RC2 are connected in series between the negative pole of the Cell5 and the terminal VC4, and the negative voltage of the Cell5 (or the positive voltage of the Cell 4) is transmitted to the Cell voltage measurement circuit 200 through the terminal VC 4.

When the Cell discharge switch 305 is turned on, the Cell5 is discharged along the discharge path BP1 formed by the Cell5, the Cell balancing resistor RB1, the Cell discharge switch 305, and the Cell balancing resistor RB 1.

Fig. 7 illustrates a partial configuration showing a connection relationship between the cell balancing IC and the battery cell assembly according to an exemplary embodiment.

In fig. 7, a plurality of resistors RC3 and RC4, Cell balancing resistors RB3 and RB4, Cell balancing switch 105, Cell balancing controller 100, and Cell voltage measuring circuit 400 connected to Cell5 are illustrated.

The resistors RC3 and RC4 are connected in series between the positive electrode of the Cell5 and the terminal vc5, and the positive voltage of the Cell5 (or the negative voltage of the Cell 6) is transmitted to the Cell voltage measurement circuit 400 through the terminal vc 5. A resistor RB3 is connected between the positive pole of Cell5 and terminal cb5h, a first end of Cell balancing switch 105 is connected to terminal cb5h, a resistor RB4 is connected between the negative pole of Cell5 and terminal cb5l, and a second end of Cell balancing switch 105 is connected to terminal cb5 l. The cell balance switch 105 performs a switching operation depending on the gate signal VG5 supplied from the cell balance controller 100.

The resistors RC3 and RC4 are connected in series between the negative pole of the Cell5 and the terminal vc4, and the negative voltage of the Cell5 (or the positive voltage of the Cell 4) is transmitted to the Cell voltage measurement circuit 400 through the terminal vc 4.

When the Cell discharge switch 105 is turned on, the Cell5 discharges along the discharge path BP2 formed by the Cell5, the Cell balancing resistor RB3, the Cell discharge switch 105, and the Cell balancing resistor RB 4.

Fig. 8 illustrates a flowchart showing a cell balancing control method depending on a voltage difference between cells of a main control circuit according to an exemplary embodiment.

First, the main control circuit 30 calculates a voltage difference between the cells for each of the cells. The voltage difference between the cells may indicate a difference between the cell voltage of at least one of two cells adjacent to each of the cells and the cell voltage of the corresponding cell (S1).

The main control circuit 30 compares the voltage difference between the cells with a first reference voltage (e.g., 1V) (S2), selects a cell, of which the voltage difference between the cells is equal to or higher than the first reference voltage, as a cell balancing target cell as a result of the comparison, and controls both the cell monitoring IC 20 and the cell balancing IC10 to perform a cell balancing operation (S3). That is, in the cell monitoring IC10 and the cell balancing IC10, the first cell balancing current (e.g., 100mA) and the second cell balancing current (e.g., 60mA) may flow through the first cell balancing resistors RB1 and RB2 and the second cell balancing resistors RB3 and RB4 connected to the corresponding cells.

When the voltage difference between the cells is lower than the first reference voltage in step S2, the main control circuit 30 compares the voltage difference between the cells with a second reference voltage (e.g., 0.5V) (S4), selects a cell, of which the voltage difference between the cells is lower than the first reference voltage and higher than or equal to the second reference voltage, as a cell balancing target cell as a result of the comparison, and controls the cell monitoring IC 20 to perform a cell balancing operation (S5). That is, in the cell monitoring IC 20, the first cell balancing current may flow through the first cell balancing resistors RB1 and RB2 connected to the corresponding cell.

When the voltage difference between the cells is lower than the second reference voltage in step S4, the main control circuit 30 compares the voltage difference between the cells with the cell balancing threshold voltage (S6), selects a cell, of which the voltage difference between the cells is higher than or equal to the cell balancing threshold voltage, as a cell balancing target cell as a result of the comparison, and controls the cell balancing IC10 to perform a cell balancing operation (S7). That is, in the cell balancing IC10, the second cell balancing current may flow through the second cell balancing resistors RB3 and RB4 connected to the corresponding cells.

As a result of the comparison in step S6, cell balancing is not performed when the voltage difference between the cells is less than the cell balancing threshold voltage (S8).

In addition, the main control circuit 30 may control the cell balancing method differently depending on the temperature of each of the first and second cell balancing resistors corresponding to each of the cells.

Fig. 9 illustrates a flowchart showing a cell balancing control method depending on a temperature of a cell balancing resistor of a main control circuit according to an exemplary embodiment.

The main control circuit 30 calculates the temperature of each of the first cell balancing resistors and the second cell balancing resistors depending on the measurement value received from the temperature sensor 13 (S9).

When the temperature sensor 13 includes a plurality of temperature sensors arranged adjacent to the first cell balancing resistor and the second cell balancing resistor connected to each of the cells, the main control circuit 30 may receive a measurement value from each of the temperature sensors to calculate the temperature of each of the first cell balancing resistor and the second cell balancing resistor.

However, the present invention is not limited thereto, and the temperature sensor 13 may include a plurality of temperature sensors arranged adjacent to each of the first cell balancing resistor and the second cell balancing resistor connected to the cell at a specific position among the cells or at least two cells spaced apart from each other, etc.

The main control circuit 30 compares the temperature of each of the first cell balancing resistors and the second cell balancing resistors with a reference temperature (e.g., 100 degrees) (S10). Hereinafter, the temperature of the first cell balance resistor is referred to as a first resistance temperature, and the temperature of the second cell balance resistor is referred to as a second resistance temperature.

When the second resistance temperature is higher than or equal to the reference temperature (e.g., 100 degrees) and the first resistance temperature is lower than the reference temperature as a result of the comparison in step S10, the cell-balancing target cell is discharged by using the first cell-balancing current through the first cell-balancing resistor (S11).

When the first resistance temperature is higher than or equal to the reference temperature and the second resistance temperature is higher than or equal to the reference temperature as a result of the comparison in step S10, the cell balancing target cell is discharged by using the second cell balancing current through the second cell balancing resistor (S12).

The method of selecting the monomer to balance the target monomer may depend on the flow chart shown in fig. 8.

For example, when the voltage difference between the cells is higher than or equal to the first reference voltage, the main control circuit 30 controls the cell monitoring IC10 and the cell balancing IC 20 to discharge the corresponding cell by using the first cell balancing current and the second cell balancing current through the first cell balancing resistors RB1 and RB2 and the second cell balancing resistors RB3 and RB 4. In this case, however, the main control circuit 30 may control the cell monitoring IC10 and the cell balancing IC 20 to use the second cell balancing resistors RB3 and RB4 when the temperature of the first cell balancing resistors RB1 and RB2 is higher than or equal to the reference temperature, and the main control circuit 30 may control the cell monitoring IC10 and the cell balancing IC 20 to use the first cell balancing resistors RB1 and RB2 when the temperature of the second cell balancing resistors RB3 and RB4 is higher than or equal to the reference temperature. The first cell balancing resistors RB1 and RB2 may also be used for cell balancing when the temperature of the first cell balancing resistors RB1 and RB2 is decreased from a temperature equal to or higher than a reference temperature to a temperature lower than the reference temperature. Similarly, the second cell balancing resistors RB3 and RB4 may also be used for cell balancing when the temperature of the second cell balancing resistors RB3 and RB4 is decreased from a temperature equal to or higher than the reference temperature to a temperature lower than the reference temperature.

In addition, when the voltage difference between the cells is higher than or equal to the second reference voltage and less than the first reference voltage, the main control circuit 30 controls the cell monitoring IC10 and the cell balancing IC 20 to discharge the corresponding cell by using the first cell balancing current through the first cell balancing resistors RB1 and RB 2. In this case, however, when the temperatures of the first cell balancing resistors RB1 and RB2 are equal to or higher than the reference temperature, the main control circuit 30 may control the cell monitoring IC10 and the cell balancing IC 20 to use the second cell balancing resistors RB3 and RB4 instead of the first cell balancing resistors RB1 and RB 2. When the temperature of the first cell balancing resistors RB1 and RB2 is decreased from a temperature equal to or higher than the reference temperature to a temperature lower than the reference temperature, the first cell balancing resistors RB1 and RB2 may be used for cell balancing instead of the second cell balancing resistors RB3 and RB 4.

In addition, when the voltage difference between the cells is higher than or equal to the cell balancing threshold voltage and less than the second reference voltage, the main control circuit 30 controls the cell monitoring IC10 and the cell balancing IC 20 to discharge the corresponding cell by using the second cell balancing current through the second cell balancing resistors RB3 and RB 4. In this case, however, when the temperatures of the second cell balancing resistors RB3 and RB4 are equal to or higher than the reference temperature, the main control circuit 30 may control the cell monitoring IC10 and the cell balancing IC 20 to use the first cell balancing resistors RB1 and RB2 instead of the second cell balancing resistors RB3 and RB 4. When the temperature of the second cell balancing resistors RB3 and RB4 is decreased from a temperature equal to or higher than the reference temperature to a temperature lower than the reference temperature, the second cell balancing resistors RB3 and RB4 may be used for cell balancing instead of the first cell balancing resistors RB1 and RB 2.

In this way, according to the present exemplary embodiment, the battery management system may perform cell balancing by using at least two cell balancing currents by adding a cell balancing IC, unlike using only an existing cell monitoring IC. Then, it is possible to reduce the time required for cell balancing by using a larger cell balancing current than in the prior art, and to provide an effect of performing more complicated cell balancing.

While the invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not to be limited to the disclosed embodiments, but on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.