TW202308259A - Battery cell balance circuit and method of operating the same - Google Patents

Abstract

A battery cell balance circuit includes an AC/DC converter, a plurality of battery cells, a plurality of switches, an isolated DC/DC converter, a circuit switch, and a control unit. The AC/DC converter receives an AC power. The battery cells are connected in series to form a battery link. Each switch is correspondingly connected to one battery cell. The isolated DC/DC converter is coupled to the switches and coupled to the battery link in series. The circuit switch is coupled between the AC/DC converter, the isolated DC/DC converter, and the plurality of switches. The control unit provides a plurality of control signals to correspondingly control the plurality of switches and the circuit switch.

Description

Battery balancing circuit and method of operation thereof

The invention relates to a battery balancing circuit and its operating method, especially to an active battery balancing circuit and its operating method.

In the application of high-energy (high-power) and high-voltage energy storage systems, it is usually not possible for a single battery to operate. Therefore, in order to achieve high-energy (high-power) and high-voltage energy storage applications, multiple batteries will be used. Modularization of battery cell packaging. As shown in FIG. 1 , it is a three-dimensional schematic diagram of a battery module with multiple battery cells in the prior art. Each battery module 100 has 18 battery cells 101-10N arranged in two rows and connected in series. Therefore, in the application of the energy storage system, multiple sets of battery modules 100 can be provided in parallel to achieve high energy (high power) and high voltage power supply applications.

For a single battery cell 101 - 10N , when the battery cell 101 - 10N ages, there will be an abnormal phenomenon that it is easy to fully charge and easy to discharge. Taking the single battery module 100 shown in FIG. 1 as an example, it has 18 battery cells 101-10N. Once one of them ages ahead of time, the battery cell with more serious aging will not be able to charge or charge the other 17 battery cells. The impact of discharge will be: when charging, the charging voltage of the battery cell with serious aging rises faster, so for the entire battery module 100, in the continuous normal charging process, the battery cell with serious aging will be overcharged The condition of the battery (other battery cells may not be fully charged), or even damage. On the contrary, when discharging, the discharge voltage of the more seriously aged battery cell will drop faster, so for the entire battery module 100, in the continuous normal discharge process, the more seriously aged battery cell will be over-discharged condition (other battery cells may not be fully discharged), or even damage.

Therefore, how to design a battery balancing circuit and its operation method to solve the problems and technical bottlenecks in the prior art is an important subject studied by the inventor of the present case.

An object of the present invention is to provide a battery balancing circuit to solve the problems in the prior art.

In order to achieve the purpose disclosed above, the battery balancing circuit proposed by the present invention includes an AC-DC converter, a plurality of battery cells, a plurality of switches, an isolated DC-DC converter, a line switch and a control unit. The AC-DC converter receives AC power. A plurality of battery cells are connected in series to form a battery chain. Each switch is correspondingly connected to each battery cell. The input side of the isolated DC-DC converter is coupled in parallel with the input sides of the switches, and the output side of the isolated DC-DC converter is coupled in series with the battery chain. The line switch is coupled between the AC-DC converter and the isolated DC-DC converter, the switches. The control unit provides multiple control signals to correspondingly control the switches and the line switches.

Another object of the present invention is to provide an operation method of a battery balancing circuit to solve the problems in the prior art.

In order to achieve the purpose disclosed above, the battery balancing circuit operation method proposed by the present invention, the battery balancing circuit includes: a plurality of battery cells connected in series to form a battery chain; a plurality of switches, each switch correspondingly connected to each battery cell; a circuit switch , coupled between the DC power supply and the switches. The operation method includes: during the charging process of the battery cells, when the battery voltage of any battery cell is detected to be higher than the upper threshold voltage, the switch corresponding to the battery cell is controlled to be turned on; the electric energy of the battery cell is released to the battery chain; During the discharge process of the battery cells, when the battery voltage of any battery cell is detected to be lower than the lower threshold voltage, the control circuit switch is turned on, and the switch corresponding to the battery cell is controlled to be turned on; and the battery cell receives electric energy from the DC power supply.

With the proposed battery balancing circuit and the operation method of the battery balancing circuit, the battery voltage is adjusted through the energy release and replenishment of the aging battery cells, that is, when the charging process voltage increases due to the decline in the battery cell’s storage capacity When it is faster, the energy of the higher voltage battery cell is transmitted to the battery chain, and when the voltage of the battery cell drops faster during the discharge process due to the decline in storage capacity, the energy of the lower voltage battery cell is replenished through the AC power supply, so , can maintain the battery cells with serious aging to operate normally in the whole battery module, so that in the application of the energy storage system, the operation of the battery module can be continuously maintained without frequent replacement of the battery cells. Wait until the annual maintenance to replace the seriously aging battery cells to improve the economic benefits of energy storage system applications.

In order to further understand the technology, means and effects that the present invention adopts to achieve the predetermined purpose, please refer to the following detailed description and accompanying drawings of the present invention. It is believed that the purpose, characteristics and characteristics of the present invention can be obtained from this in depth and For specific understanding, however, the accompanying drawings are provided for reference and illustration only, and are not intended to limit the present invention.

Hereby, the technical content and detailed description of the present invention are described as follows in conjunction with the drawings.

Before detailing the technical features of the battery balancing circuit and its operating method of the present invention, a brief description will be given of the passive battery balancing technology and the active battery balancing technology. Passive battery balancing technology refers to dissipating the energy of higher-voltage battery cells through energy-consuming components. The common practice is: each battery cell is connected to a resistance element in parallel through a switch circuit, and the higher-voltage voltage is reduced by controlling the conduction of the switch and the resistance element connected in parallel. The energy of the battery cells is consumed, thereby reducing the voltage of the battery cells to achieve a voltage balance among the battery cells.

Compared with passive battery balancing technology, active battery balancing technology refers to the redistribution of energy between batteries, for example: using energy storage elements (such as inductors or capacitors) to temporarily store the energy of higher voltage battery cells, Then release the temporarily stored energy to the lower voltage battery cells to achieve the effect of voltage balance of each battery cell.

However, compared with the existing active battery balancing technology disclosed above, the present invention proposes different technical means to achieve the effect of active battery balancing.

Please refer to FIG. 2 , which is a circuit block diagram of the first embodiment of the switch unit of the battery balancing circuit of the present invention. As shown in FIG. 2 , the battery balancing circuit has a plurality (m) of battery cells Cell 1 -Cell m, and the battery cells Cell 1 -Cell m are connected in series to form a battery chain L _CELL . In the configuration framework of this embodiment, since the positive and negative poles (terminals) of each battery cell Cell 1-Cell m are connected to a switch unit, that is, the positive and negative poles of the battery cell Cell 1 are respectively connected to the switch units S _1A and S _1B , the positive and negative poles of the battery cell Cell 2 are respectively connected to the switch units S _2A and S _2B , and so on, so the number of switch units is twice the number of battery cells. Therefore, if the number of battery cells Cell 1-Cell m is 18, the number of switch units is 36. As shown in FIG. 2, the battery cells Cell 1-Cell m are connected to the charging and discharging circuit 200 through the switch units S _1A -S _mB , wherein the positive poles of the battery cells Cell 1-Cell m are connected to the charging and discharging circuit 200 through the switch units S _1A -S _mA respectively. The positive power supply end or the positive power receiving end of the charging and discharging circuit 200 . Similarly, the negative poles of the battery cells Cell 1 -Cell m are respectively connected to the negative power supply terminal or the negative power receiving terminal of the charging and discharging circuit 200 through the switch units S _1B -S _mB .

Incidentally, the charging and discharging circuit 200 shown in FIG. 2 is only for illustration when the voltage of (at least one of) the battery cells Cell 1-Cell m (at least one) needs to be charged or needs to be discharged when the voltage is too high. The charging circuit and discharging circuit that work together. That is, the charge-discharge circuit 200 can be a circuit having both charge and discharge functions, or the charge-discharge circuit 200 is two sets of circuits with separate charge and discharge functions, but this does not limit the present invention.

Please refer to FIG. 3 , which is a circuit block diagram of the second embodiment of the switch unit of the battery balancing circuit of the present invention. As shown in FIG. 3 , the battery balancing circuit has a plurality (m) of battery cells Cell 1 -Cell m, and the battery cells Cell 1 -Cell m are connected in series to form a battery chain L _CELL . In the configuration structure of this embodiment, since the positive pole of the first battery cell Cell 1 is connected to a switch unit S ₁ , and the negative pole of the last battery cell Cell m is connected to a switch unit S _m+1 , and the middle battery cell Cell The positive and negative terminals of 2-Cell m-1 are connected to a switch unit S ₂ -S _m , and the battery cell Cell 1-Cell is realized through a switch group Sa composed of 4 switch units (detailed later). m charging and discharging operations, so the total number of switch units is the number of battery cells plus 5. Therefore, if the number of battery cells Cell 1-Cell m is 18, the number of switch units is 23.

Please refer to FIG. 4 , which is a circuit block diagram of the third embodiment of the switch unit of the battery balancing circuit of the present invention. Compared with the embodiments shown in Fig. 2 and Fig. 3, the switching unit shown in Fig. 4 is realized by relays RL1-RL6 (taking the battery chain L _CELL with 6 battery cells as an example), in other words, through the relay RL1 -Excitation control of RL6 to achieve switch on and off effects, providing a path for battery cell Cell 1-Cell 6 charge and discharge operations.

Specifically, taking the embodiment of FIG. 4 as an example, the battery balancing circuit of the present invention mainly includes an AC-DC converter 300, a plurality of battery cells Cell 1-Cell 6, a plurality of switching units RL1-RL6, and an isolated DC-DC converter 400. , a line switch S _C and a control unit 500 . The AC-DC converter 300 receives the AC power V _AC and converts the AC power V _AC into a DC power. A plurality of battery cells Cell 1-Cell 6 are connected in series to form a battery chain L _CELL . Each switch unit RL1-RL6 is correspondingly connected to each battery cell Cell 1-Cell 6. In the embodiment shown in FIG. 4 , each switch unit RL1-RL6 is an electromagnetic relay (relay), which utilizes the principle of electromagnetic effect to excite the coil to change the state of the contact to realize the switch function of on and off. Furthermore, the number of switch units RL1-RL6 is the same as that of battery cells Cell 1-Cell 6, which means that the first battery cell Cell 1 is connected to the first switch unit RL1, and the second battery cell Cell 2 is connected to the second switch unit RL2... analogy.

The input side of the isolated DC-DC converter 400 is coupled in parallel to the first side of each switch unit RL1-RL6. As shown in FIG. 4, the input side of the isolated DC-DC converter 400 has a positive pole and a negative pole, and the positive pole is connected via The positive pole of the DC power converted by the AC-DC converter 300 is connected to the negative pole of the DC power converted by the AC-DC converter 300 . Each electromagnetic relay has a first side and a second side, and has a positive pole and a negative pole respectively, the positive pole of the first side is coupled to the positive pole of the DC power supply and the positive pole of the input side of the isolated DC-DC converter 400, and the negative pole of the first side It is coupled to the negative pole of the DC power supply and the negative pole of the input side of the isolated DC-DC converter 400 , and the second side is respectively coupled to the positive pole and the negative pole of the corresponding battery cell. In other words, the positive poles of the first side of all the magnetic relays are coupled together, and then jointly coupled to the positive pole of the DC power supply and the positive pole of the input side of the isolated DC-DC converter 400, while the negative poles of the first side of the magnetic relays are coupled to Together, they are jointly coupled to the negative pole of the DC power supply and the negative pole of the input side of the isolated DC-DC converter 400 .

Furthermore, the output side of the isolated DC-DC converter 400 is coupled to the battery chain L _CELL in series. As shown in FIG. 4 , the output side of the isolated DC-DC converter 400 has a positive pole and a negative pole, wherein the positive pole is coupled to the battery chain L The positive terminal of _{the CELL} (that is, the positive terminal of the first battery cell Cell 1), and the negative terminal of the battery chain L _CELL (that is, the negative terminal of the sixth battery cell Cell 6) are coupled, so that the output side of the isolated DC-DC converter 400 The battery chain L _CELL is coupled in series.

The line switch S _C is coupled between the AC-DC converter 300 and the isolated DC-DC converter 400 , and is also between the AC-DC converter 300 and the switch units RL1 - RL6 . Wherein the line switch S _C can be an electromagnetic relay switch or a transistor switch (such as MOSFET), but the present invention is not limited by any one.

The battery balancing circuit provided by the present invention is in the charging process of these battery cores Cell 1-Cell 6, when all battery cores Cell 1-Cell 6 are in a normal state, then when fully charged, all battery cores Cell 1-Cell 6 are in a normal state. The battery voltage of Cell 6 will not be too high. Conversely, during the discharge process of these battery cells Cell 1-Cell 6, when all the battery cells Cell 1-Cell 6 are in a normal state, the battery voltage of all the battery cells Cell 1-Cell 6 will be lower when the battery is completely discharged. Not too low.

The battery balancing circuit provided by the present invention is that when the battery voltage of any one of the battery cells Cell 1-Cell 6 is too high during the charging process of the battery cells Cell 1-Cell 6, the voltage of the (over-voltage) battery cell will The electric energy is released to the battery chain L _CELL , so that the battery voltage of the battery cell is reduced to prevent overcharging. Furthermore, when the battery voltage of any one of the battery cells Cell 1-Cell 6 is too low during the discharge process of the battery cells Cell 1-Cell 6, the (low voltage) battery cell is provided with electrical energy through the AC power supply V _AC , to increase the battery voltage of the battery cell without over-discharging.

Specifically, as shown in FIG. 4, during the charging process of the battery cells Cell 1-Cell 6, when the control unit 500 detects that the battery voltage of any battery cell Cell 1-Cell 6 is higher than the upper threshold voltage, the control unit 500 The switching unit RL1-RL6 of the battery cell corresponding to the overvoltage is controlled to be turned on through the provided switch control signal SRL1-SRL6, so that the electric energy of the battery cell RL1-RL6 with the overvoltage is released to the Battery chain L _CELL . For example, during the charging process of the battery cells Cell 1-Cell 6 of the battery chain L _CELL , when the control unit 500 detects that the battery voltage of the first battery cell Cell 1 is too high (ie higher than the upper threshold voltage) , the control unit 500 controls the first switch unit RL1 to conduct through the first switch control signal SRL1, so that the electric energy of the first battery cell Cell 1 is released to the battery chain L _CELL through the first switch unit RL1 and the isolated DC-DC converter 400, In addition to reducing the battery voltage of the first battery cell Cell 1 to prevent overcharging, the electric energy of the first battery cell Cell 1 can also be used as electric energy for charging the battery chain L _CELL without wasting it. Similarly, the operating principles of other battery cells are the same as those described above, and will not be repeated here.

During the discharge process of these battery cells Cell 1-Cell 6, when the control unit 500 detects that the battery voltage of any battery cell Cell 1-Cell 6 is lower than the lower threshold voltage, the control unit 500 controls the battery through the provided switch control signal S _CC The line switch S _C is turned on, and the switch unit RL1-RL6 corresponding to the battery cell with too low voltage is controlled to be turned on through the provided switch control signal SRL1-SRL6, so that the battery cell with too low voltage receives power from the _AC power supply V AC. The lower threshold voltage is smaller than the upper threshold voltage disclosed above. For example, during the discharge process of the battery cells Cell 1-Cell 6 of the battery chain L _CELL , when the control unit 500 detects that the battery voltage of the first battery cell Cell 1 is too low (ie lower than the lower threshold voltage) , the control unit 500 controls the line switch S _C to be turned on through the switch control signal S _CC , and controls the first switch unit RL1 to be turned on through the first switch control signal SRL1, so that the AC power supply V _AC is connected to the first switch unit RL1 through the line switch S _C The first battery cell Cell 1 provides electric energy to increase the battery voltage of the first battery cell Cell 1 without over-discharging. Similarly, the operating principles of other battery cells are the same as those described above, and will not be repeated here.

In this way, through the battery balancing circuit, the battery voltage is adjusted through the energy release and replenishment of the aging battery cores, that is, when the battery core voltage rises faster during the charging process due to the decline in storage capacity, the higher voltage will be adjusted. The energy of the battery cell is transmitted to the battery chain L _CELL , and when the voltage of the battery cell drops rapidly during the discharge process due to the decline in the storage capacity, the AC power supply is used to supplement the energy of the battery cell with a lower voltage. In this way, the aging battery can be maintained The voltage of the battery cell is roughly the same as the voltage of other battery cells to ensure the normal operation of the entire battery module, so that in the application of the energy storage system, the operation of the battery module can be continuously maintained without frequent replacement of the battery cells. Wait until the annual maintenance to replace the seriously aging battery cells to improve the economic benefits of energy storage system applications.

In addition, referring back to FIG. 4 , in the embodiment of the present invention, the battery balancing circuit further includes overcurrent protection elements corresponding to the battery cells Cell 1 -Cell 6 , such as but not limited to fuses F1 -F7 . In this way, when the battery cells Cell 1-Cell 6 are in the process of charging and discharging, if an overcurrent abnormality occurs, the corresponding fuses F1-F7 can be used to provide overcurrent protection to realize the protection of the battery cells Cell 1-Cell 6 protection.

Please refer to Fig. 5, which is a circuit block diagram of a preferred embodiment of the battery balancing circuit of the present invention, wherein Fig. 5 is an embodiment matching the front-exposed Fig. 3 (i.e. the second embodiment of the switch unit), the battery The balance circuit mainly includes an AC-DC converter 300, an isolated DC-DC converter 400, a control unit 500, a plurality (6) of battery cells Cell 1-Cell 6 connected in series to form a battery chain L _CELL , a plurality of (7 ) switch units S ₁ -S ₇ , and a switch group Sa including switching switch units Sa1, Sa2, Sb1, Sb2. The control unit 500 provides switch control signals S1c-S7c to control the switch units _S1 - _S7 respectively, switch control signals Sa1c-Sb2c respectively control the switch units Sa1, Sa2, Sb1, Sb2, and the switch control signal S _CC controls the line switch S _C. In this embodiment, due to the design of the configuration (connection relationship) of the switch units _S1 - _S7 , the number of switch units can be greatly reduced for a battery module with more battery cells (as shown in Figure 3 above). description), therefore, in conjunction with the switching on and off of the switching units Sa1, Sa2, Sb1, and Sb2, a path for charging and discharging operations of the battery cells Cell 1-Cell 6 can be realized.

Specifically, as shown in FIG. 5, during the charging process of the battery cells Cell 1-Cell 6, when the control unit 500 detects that the battery voltage of any battery cell Cell 1-Cell 6 is higher than the upper threshold voltage, the control unit 500 Control the switch unit S1- _S7 of the battery cell corresponding to the overvoltage to be turned on through the provided switch control signal _S1c -S7c, so that the electric energy of the battery cell RL1-RL6 with the overvoltage is released through the isolated DC-DC converter 400 to the battery chain L _CELL . For example, during the charging process of the battery cells Cell 1-Cell 6 of the battery chain L _CELL , when the control unit 500 detects that the battery voltage of the first battery cell Cell 1 is too high (ie higher than the upper threshold voltage) , the control unit 500 controls the conduction of the first switch unit Sa1 through the first switch control signal Sa1c, controls the conduction of the second switch unit Sa2 through the second switch control signal Sa2c, and controls the first switch unit through the first switch control signal S1c S ₁ is turned on, and the second switch control signal S2c controls the second switch unit S ₂ to be turned on, so that the electric energy of the first battery cell Cell 1 passes through the first switch unit S ₁ , the second switch unit S ₂ , the first switching unit Sa1, The second switching unit Sa2 and the isolated DC-DC converter 400 are released to the battery chain L _CELL . In addition to reducing the battery voltage of the first battery cell Cell 1 so as not to cause overcharging, the first battery cell Cell The electric energy of 1 can also be used as the electric energy charged by the battery chain L _CELL .

Similarly, during the charging process of the battery cells Cell 1-Cell 6 of the battery chain L _CELL , when the control unit 500 detects that the battery voltage of the second battery cell Cell 2 is too high, the control unit 500 through the third switching switch The control signal Sb1c controls the conduction of the third switch unit Sb1, the fourth switch control signal Sb2c controls the conduction of the fourth switch unit Sb2, and controls the conduction of the second switch unit _S2 through the second switch control signal S2c, and the third switch control signal S3c controls the third switch unit _S3 to conduct, so that the electric energy of the second battery cell Cell 2 passes through the second switch unit _S2 , the third switch unit _S3 , the third switch unit Sb1, the fourth switch unit Sb2 and the isolation type The DC-DC converter 400 releases to the battery chain L _CELL , in addition to reducing the battery voltage of the second battery cell Cell 2 to avoid overcharging, the electric energy of the second battery cell Cell 2 can also be used as the battery chain L The electrical energy charged by _{the CELL} .

During the discharge process of these battery cells Cell 1-Cell 6, when the control unit 500 detects that the battery voltage of any battery cell Cell 1-Cell 6 is lower than the lower threshold voltage, the control unit 500 controls the battery through the provided switch control signal S _CC The line switch S _C is turned on, and the switch unit S ₁ -S ₇ corresponding to the battery cell with too low voltage is controlled to be turned on through the provided switch control signal S1c-S7c, so that the battery cell with too low voltage receives power from the _{AC power supply V AC} . For example, during the discharge process of the battery cells Cell 1-Cell 6 of the battery chain L _CELL , when the control unit 500 detects that the battery voltage of the first battery cell Cell 1 is too low (ie lower than the lower threshold voltage) , the control unit 500 controls the line switch _SC to conduct through the switch control signal _SCC , and controls the first switch unit Sa1 to conduct through the first switch control signal Sa1c, and controls the second switch unit Sa2 to conduct through the second switch control signal Sa2c. , and through the first switch control signal S1c to control the first switch unit _S1 to conduct, and the second switch control signal S2c to control the second switch unit _S2 to conduct, so that the AC power V _AC passes through the line switch S _C and the first switch unit Sa1 , The second switching unit Sa2, the first switching unit _S1 and the second switching unit _S2 provide electric energy to the first battery cell Cell 1, so that the battery voltage of the first battery cell Cell 1 increases without over-discharging situation.

Similarly, during the discharge process of the battery cells Cell 1-Cell 6 of the battery chain L _CELL , when the control unit 500 detects that the battery voltage of the second battery cell Cell 2 is too low, the control unit 500 controls the signal S through the switch _{The CC} control line switch _SC is turned on, and the third switch unit Sb1 is controlled to be turned on through the third switch control signal Sb1c, the fourth switch unit Sb2 is controlled to be turned on by the fourth switch control signal Sb2c, and the second switch control signal S2c is used to control the conduction of the fourth switch unit Sb2. Control the second switch unit _S2 to conduct, and the third switch control signal _S3c controls the third switch unit _S3 to conduct, so that the AC power source V _AC is connected to the first switch unit Sb1, Sb2 and The second switch unit S ₂ and the third switch unit S ₃ provide electric energy to the second battery cell Cell 2 to increase the battery voltage of the second battery cell Cell 2 without over-discharging.

To sum up, the control principle of the switch group Sa (including switch units Sa1, Sa2, Sb1, Sb2) and switch units _S1 - _{S7 of} the battery balancing circuit shown in FIG. 5 is based on the AC-DC converter 300 The positive and negative polarities of the converted output DC power correspond to the positive and negative polarities of the battery cells Cell 1-Cell 6 whose battery voltage is too high (or too low), so as to realize the release and supplement of the permeable energy of the aging battery cells And adjust the battery voltage.

Similarly, the first embodiment of the switch unit shown in FIG. 2 can also be applied to the structure shown in FIG. 5 , and the control principle of the switch unit is similar to that in FIG. 5 , so detailed control and operation descriptions will not be repeated here.

Please refer to FIG. 6 , which is a detailed circuit block diagram of a preferred embodiment of the battery balancing circuit of the present invention. 6 more specifically reveals that the AC-DC converter 300 includes an AC-DC conversion circuit 301 and a non-isolated DC-DC conversion circuit (such as a step-down conversion circuit, which includes a switch S1, a switch S2, an inductor L1, a capacitor C1, and a resistor R1). The control unit 500 includes a battery charging control unit 501 and a controller 502 to control the charging and discharging operations of the battery cells Cell 1 -Cell 6 . In addition, the battery balancing circuit further includes the controller area network CAN (including the controller area network integrated circuit CAN IC and the controller area network bus), so that the control unit 500 detects and controls the overall circuit. External transmission through the controller area network (CAN), so that remote operators can obtain monitoring and control, and when the system is abnormal, it can be repaired in real time to maintain the normal operation of the system.

Please refer to FIG. 7 , which is a flow chart of the operation method of the battery balancing circuit of the present invention. The battery balancing circuit includes: a plurality of battery cells connected in series to form a battery chain; a plurality of switches, each switch correspondingly connected to each battery cell; a line switch, coupled between the AC power supply and the switches. For the specific structure of the battery balancing circuit, please refer to the foregoing disclosure, and will not be repeated here. The operation method of the battery balancing circuit of the present invention includes:

The battery cells can be charged (S11) and discharged (S21). During the charging process of the battery cells (S11), when it is detected that the battery voltage of any battery cell is higher than the upper threshold voltage, the switch corresponding to the battery cell is controlled to be turned on (S12). Further, the electric energy of the battery core is released to the battery chain (S13). During the discharge process of the battery cells (S21), when it is detected that the battery voltage of any battery cell is lower than the lower threshold voltage, the control circuit switch is turned on, and the switch corresponding to the battery cell is controlled to be turned on (S22). Further, the battery cell receives power from an AC power source (S23).

In summary, the present invention has the following features and advantages:

1. Through the battery balancing circuit of the present invention, the battery voltage is adjusted through the release and supplement of energy of the battery cells with serious aging, that is, when the voltage of the battery cells is too high, the energy is transmitted to the battery chain L _CELL , and When the voltage of the battery cell is too low, it is supplemented by an AC power supply. In this way, the voltage of the aging battery cell can be maintained at approximately the same voltage as the other battery cells during the charging and discharging process, so as to ensure the normal operation of the entire battery module. In the application of the energy storage system, the operation of the battery module can be continuously maintained without frequent replacement of the battery cells. Wait until the annual maintenance to replace the seriously aging battery cells to improve the economic benefits of energy storage system applications.

2. When a specific battery module is selected to be coupled to the battery balancing circuit through a solid-state switch, the switch can use a solid-state switch to replace the double-pole single-throw switch (traditional solenoid valve switch), thus increasing the battery balancing circuit. The service life of the switch is improved, and the voltage difference between the battery modules is optimized.

3. Battery chain charging: select the battery cell with the highest voltage, recycle its electric energy, feed it back to the battery chain, and extend the charging time of the battery chain.

4. Battery chain discharge: select the battery cell with the lowest voltage, charge it by the AC power supply, and extend the battery chain discharge time.

The above is only a detailed description and drawings of preferred embodiments of the present invention, but the features of the present invention are not limited thereto, and are not intended to limit the present invention. As the standard, all embodiments that conform to the spirit of the patent scope of the present invention and its similar changes should be included in the scope of the present invention. Any person familiar with the art can easily think of changes or changes in the field of the present invention. Modifications can all be covered by the patent scope of the following case.

100: battery module 101-10N: battery core 200: charging and discharging circuit Cell 1-Cell m: battery core S _1A -S _mB : switch unit S ₁ -S _m+1 : switch unit Sa: switch group 300: AC- DC converter 301: AC-DC conversion circuit 400: isolated DC-DC converter 500: control unit 501: battery charging control unit 502: controller Cell 1-Cell 6: battery cells RL1-RL6: switch unit S _C : Line switch V _AC : AC power supply L _CELL : battery chain SRL1-SRL6: switch control signal S _CC : switch control signal _S1 - _S7 : switch unit Sa1, Sa2, Sb1, Sb2: switching switch unit S1c-S7c: switch control Signal Sa1c-Sb2c: switch control signal F1-F7: fuse

FIG. 1 is a three-dimensional schematic diagram of a battery module with multiple battery cells in the prior art.

FIG. 2 is a circuit block diagram of the first embodiment of the switching unit of the battery balancing circuit of the present invention.

FIG. 3 is a circuit block diagram of the second embodiment of the switching unit of the battery balancing circuit of the present invention.

FIG. 4 is a circuit block diagram of the third embodiment of the switching unit of the battery balancing circuit of the present invention.

Fig. 5 is a circuit block diagram of a preferred embodiment of the battery balancing circuit of the present invention.

FIG. 6 is a detailed circuit block diagram of a preferred embodiment of the battery balancing circuit of the present invention.

FIG. 7 is a flowchart of the operation method of the battery balancing circuit of the present invention.

300: AC-DC Converter

400: Isolated DC-DC Converter

500: control unit

V _AC : AC power

Cell 1-Cell 6: battery cell

L _CELL : battery chain

S ₁ -S ₇ : switch unit

Sa1, Sa2, Sb1, Sb2: changeover switch unit

S _C : Line switch

F1-F7: Fuses

S _CC : switch control signal

Sa1c-Sb2c: switch control signal

S1c-S7c: switch control signal

Claims (16)

A battery balancing circuit comprising: An AC-DC converter, receiving an AC power source and converting the AC power source into a DC power source; A plurality of battery cells connected in series to form a battery chain; A plurality of switches, each of which is correspondingly connected to each of the battery cells; An isolated DC-DC converter, an input side of the isolated DC-DC converter is coupled in parallel to an input side of each switch, an output side of the isolated DC-DC converter is coupled in series to the battery chain ; a line switch coupled between the AC-DC converter and the isolated DC-DC converter, the switches; and A control unit provides multiple control signals to correspondingly control the switches and the line switch. The battery balancing circuit as described in claim 1, wherein when the control unit detects that a battery voltage of any battery cell is higher than an upper threshold voltage, the control unit controls the switch corresponding to the battery cell to turn on, so that the battery cell The electric energy released to the battery chain through the isolated DC-DC converter. The battery balancing circuit as described in Claim 1, wherein when the control unit detects that the battery voltage of any battery cell is lower than a lower critical voltage, the control unit controls the circuit switch to be turned on, and controls the switch corresponding to the battery cell conduction, so that the battery core receives electric energy from the AC power source. The battery balancing circuit as described in Claim 1, wherein the switches are electromagnetic relays; A positive first end of each switch is connected to the positive pole of the DC power supply, and a negative first end of each switch is connected to the negative pole of the DC power supply; A positive second end of each switch is correspondingly connected to the positive pole of the battery core, and a negative second end of each switch is connected to the negative pole of the battery core. The battery balancing circuit as claimed in item 1, wherein the switches include a plurality of switching units; The positive poles of the battery cells are respectively connected to one end of a switch unit, and the other ends of the switch units are connected together and connected to the positive pole of the DC power supply; The negative poles of the battery cores are respectively connected to one end of a switch unit, and the other ends of the switch units are commonly connected to the negative pole of the DC power supply. The battery balancing circuit as claimed in item 1, wherein the switches include a plurality of switch units and a switch group; The positive pole of the first of the battery cells is connected to one end of a switch unit, the negative pole of the last of the battery cells is connected to one end of a switch unit, and the positive and negative common terminals of the middle battery cells are connected to each other. one end of a switching unit; The switch group includes a plurality of switch units; The other ends of the switch units are correspondingly connected to the switch units, so that the positive poles of the battery cells are connected to the positive poles of the DC power supply, and the negative poles of the battery cells are connected to the negative poles of the DC power supply. The battery balancing circuit according to claim 1, wherein the AC-DC converter includes an AC-DC conversion circuit and a non-isolated DC-DC conversion circuit. The battery balancing circuit according to claim 7, wherein the non-isolated DC-DC conversion circuit is a step-down conversion circuit comprising two switches and an inductor. The battery balancing circuit as claimed in claim 1, wherein the control unit includes a battery charging control unit and a controller to provide control over charging and discharging operations of the battery cells. The battery balancing circuit as described in claim 1 further includes: A plurality of overcurrent protection elements are correspondingly connected between the switches and the battery cores. A method for operating a battery balancing circuit, the battery balancing circuit comprising: a plurality of battery cells connected in series to form a battery chain; a plurality of switches, each of which is correspondingly connected to each of the battery cells; a line switch, coupled to a DC between the power supply and the switches; the method of operation includes: During the charging process of the battery cells, when detecting that a battery voltage of any battery cell is higher than an upper threshold voltage, controlling the switch corresponding to the battery cell to be turned on; the electrical energy of the battery cell is released to the battery chain; During the discharge process of the battery cells, when the battery voltage of any battery cell is detected to be lower than a critical voltage, control the circuit switch to be turned on, and control the switch corresponding to the battery cell to be turned on; and The battery cell receives power from the DC power source. The operation method of the battery balancing circuit as claimed in item 11, wherein the battery balancing circuit further includes: An isolated DC-DC converter, an input side of the isolated DC-DC converter is coupled in parallel to a first side of each switch, an output side of the isolated DC-DC converter is coupled in series to the battery chain; Wherein, the electric energy of the battery core is released to the battery chain through the isolated DC-DC converter. The operation method of the battery balancing circuit as claimed in item 11, wherein the battery balancing circuit further includes: an AC-DC converter, receiving an AC power source and converting the AC power source into the DC power source; Wherein, the line switch is coupled to the AC power supply through the AC-DC converter. The method of operating a battery balancing circuit as claimed in claim 11, wherein the switches are electromagnetic relays; A positive first end of each switch is connected to the positive pole of the DC power supply, and a negative first end of each switch is connected to the negative pole of the DC power supply; A positive second end of each switch is correspondingly connected to the positive pole of the battery core, and a negative second end of each switch is connected to the negative pole of the battery core. The method of operating a battery balancing circuit as claimed in claim 11, wherein the switches include a plurality of switch units; The positive poles of the battery cells are respectively connected to one end of a switch unit, and the other ends of the switch units are connected together and connected to the positive pole of the DC power supply; The negative poles of the battery cores are respectively connected to one end of a switch unit, and the other ends of the switch units are commonly connected to the negative pole of the DC power supply. The method for operating a battery balancing circuit as claimed in claim 11, wherein the switches include a plurality of switch units and a switch group; The positive pole of the first of the battery cells is connected to one end of a switch unit, the negative pole of the last of the battery cells is connected to one end of a switch unit, and the positive and negative common terminals of the middle battery cells are connected to each other. one end of a switching unit; The switch group includes a plurality of switch units; The other ends of the switch units are correspondingly connected to the switch units, so that the positive poles of the battery cells are connected to the positive poles of the DC power supply, and the negative poles of the battery cells are connected to the negative poles of the DC power supply.

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