KR101485127B1 - Battery energy storage apparatus using wireless controlling method - Google Patents

Abstract

A battery energy storage device for controlling charging and discharging in a radio control manner, comprising: a cell module for receiving a wirelessly transmitted first control signal and for separately charging or discharging a cell based on the first control signal; And a battery management device for receiving the status information of the cell wirelessly transmitted and wirelessly transmitting the first control signal generated based on the received status information to the cell module.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a battery-

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001]

Electronic devices such as laptops and mobile phones and automobiles receive the necessary energy through batteries. Such a battery may be made of a battery pack including a battery cell and various circuits. The battery pack charges the battery cell through the external charger and repeats discharging to supply voltage and current to an external load such as an electronic device or a car.

Up to now, the battery packs are connected in series with the battery cells, and then the entire cell is rapidly charged with one external charger. At this time, the cells may not be uniformly charged or discharged, resulting in charge deviation or discharge deviation. The battery pack performs cell balancing to correct this deviation, and this cell balancing takes a lot of time. In particular, conventional battery management devices have problems in performing cell balancing of large-scale energy storage devices composed of hundreds or thousands of cells.

When the battery pack is charged so far, the voltage of a certain cell can reach the full charge voltage before the voltage of other cells. However, if a rapid charge is continuously performed to charge another cell that has not yet been fully charged, the fully charged cell becomes overcharged and is dangerous. In particular, if the balance of the cell is broken due to the discharge, the phenomenon becomes more severe when the battery is charged rapidly.

In addition, the battery pack up to now is wired to the battery management system (BMS). In this case, there is a limitation that the wiring is complicated and the battery pack and the battery management device are always within the range that can be connected by wire.

Korean Patent Application Publication No. 10-2011-0132977 (published Dec. 19, 2011) Battery pack and method of charging the battery pack Korean Patent Application Publication No. 10-2012-0016993 (published on Feb.27, 2012) Battery pack and active cell balancing method of battery pack

SUMMARY OF THE INVENTION It is an object of the present invention to provide a battery energy storage device of a radio control method.

A battery energy storage device for controlling charging and discharging in a wireless control scheme according to an embodiment of the present invention is a battery energy storage device for receiving a wirelessly transmitted first control signal and for individually charging or discharging cells based on the first control signal A cell module, and status information of the cell wirelessly transmitted from the cell module, generates the first control signal based on the received status information, and wirelessly transmits the generated first control signal to the cell module And a battery management device.

The cell module includes a cell in which energy is stored, a wireless communication module that wirelessly communicates with the battery management device to receive the first control signal, and a wireless communication module that transmits energy input to the charge / A charge and discharge circuit unit for receiving energy stored in the cell based on a third control signal to the charging and discharging power supply terminal and for receiving the first control signal from the wireless communication module, And a charge / discharge control unit for generating either the second control signal or the third control signal to control the charge / discharge circuit unit.

The charging and discharging control unit may collect status information of the cell and transmit the collected status information to the battery management apparatus through the wireless communication module.

The charge / discharge circuit includes a DC / DC converter, one side of the DC / DC converter is connected to the cell, and the other side of the DC / DC converter is connected to the charge / discharge power terminal.

The bidirectional DC / DC converter includes a bidirectional DC / DC converter, a bidirectional DC / AC converter, and a transformer, wherein one side of the bidirectional DC / DC converter is connected to the cell and the other side of the bidirectional DC / AC converter, the other side of the bidirectional DC / AC converter is connected to one side of the transformer, and the other side of the transformer is connected to the charge / discharge power terminal.

The charge / discharge circuit unit may further include a bidirectional AC / DC converter and a bidirectional DC / DC converter between the transformer and the charge / discharge power terminal.

A battery pack for charging or discharging cells of a plurality of cell modules on the basis of at least one control signal wirelessly transmitted; A battery management device that receives status information of each cell wirelessly transmitted from a cell module, generates the at least one control signal based on the received status information, and wirelessly transmits the generated at least one control signal to the battery pack Wherein the battery pack comprises a cell module stack in which cells of the plurality of cell modules are connected in series, a first switch located between the anode of the cell module stack and the battery pack positive terminal, individual charging and discharging of each cell module A second switch located between the power supply terminal and each cell module for receiving the first control signal, Based on the control signal comprises a wireless switch controller for controlling the second switch and the first switch.

When the battery management apparatus is charged using the battery pack positive terminal and the external charger connected to the battery pack negative terminal, the first switch is closed to rapidly charge the plurality of cell modules, and the state of each cell wirelessly transmitted from each cell module Based on the information, monitors whether the voltage of the plurality of cell modules reaches a reference voltage, and when the reference voltage is reached, generates the first control signal to cause each cell module to be individually charged and transmit it to the wireless switch control device have.

The first control signal may be a signal to open the first switch and command to close the second switch.

Each cell module includes a cell in which energy is stored, a wireless communication module that wirelessly communicates with the battery management device and receives a second control signal among control signals wirelessly transmitted by the battery management device, A charging / discharging circuit for transferring the energy input from the terminal to the cell and for transferring energy stored in the cell to the charge / discharge power supply terminal based on a fourth control signal, And a charge / discharge control unit for generating either the third control signal or the fourth control signal based on the second control signal to control the charge / discharge circuit unit.

According to the embodiment of the present invention, since the battery management device, the battery pack, and the respective cell modules communicate wirelessly, complicated wiring can be reduced. According to the embodiment of the present invention, the battery pack can be easily assembled, and the cell module can be easily replaced.

1 is a block diagram of a battery energy storage device according to an embodiment of the present invention.
2 is a block diagram of a cell module according to an embodiment of the present invention.
3 is a circuit diagram of a cell module according to an embodiment of the present invention.
4 is a circuit diagram of a cell module according to another embodiment of the present invention.
5 is a circuit diagram of a cell module according to another embodiment of the present invention.
6 and 7 are circuit diagrams of a battery pack according to an embodiment of the present invention.
8 is a block diagram of a battery energy storage device according to another embodiment of the present invention.
9 is an assembled view of a cell module according to an embodiment of the present invention.
10 is an assembled view of a battery pack according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Throughout the specification, when an element is referred to as "comprising ", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise.

Now, a battery-controlled energy storage device according to an embodiment of the present invention will be described in detail with reference to the drawings.

1 is a block diagram of a battery energy storage device according to an embodiment of the present invention.

Referring to FIG. 1, the battery energy storage device 10 includes a battery pack 100 and a battery management system (BMS) 300 for controlling the battery pack 100. The wireless battery management device 300 includes a battery management unit 310 and a wireless communication module 330. [

The battery pack 100 includes a plurality of cell modules 200 connected in series, in parallel, and in a form of a combination of series and parallel. Each cell module 200 includes a wireless communication module that wirelessly communicates with the wireless battery management device 300. The cell module 200 transfers the state information of the cell to the wireless battery management device 300 and receives the control signal from the wireless battery management device 300 to control the charging and discharging of each cell. Here, the state information of the cell includes the voltage, current and temperature of the cell.

The wireless battery management device 300 controls the switch of the battery pack 100 through the wireless communication module 330. Accordingly, the wireless battery management device 300 controls rapid charging, cell balancing, charging, and discharging of the cell module 200. Here, cell balancing refers to full cell charging by CC / CV (Constant Current / Constant Voltage) method.

Particularly, since the battery pack 100 is composed of a plurality of cell modules, there arises an unbalance problem caused by a difference in capacity between cells when charging and discharging. To solve this problem, the wireless battery management device 300 controls the cell balancing charge and discharge of each cell module 200 through the wireless communication module 330.

The wireless battery management device 300 monitors the voltage, current, and temperature information of each cell module 200 through the wireless communication module 330. The wireless battery management device 300 controls the battery pack 100 based on the monitoring information.

2 is a block diagram of a cell module according to an embodiment of the present invention.

Referring to FIG. 2, the cell module 200 includes a cell 210, and a circuit portion 230. The circuit unit 230 includes a charge / discharge circuit unit 231, a charge / discharge control unit 233, and a wireless communication module 235. The wireless communication module 235 includes an antenna 250.

The cell 210 is connected to the positive terminal 271 and the negative terminal 272 and rapidly charged and discharged. When the positive terminal 271 and the negative terminal 272 are connected to an external charger (not shown), the cell 210 is charged. When the positive terminal 271 and the negative terminal 272 are connected to a load (not shown), the cell 210 is discharged.

The charge / discharge circuit portion 231 is located between the charge / discharge power supply terminals 273 and 274 and the cell 210. The charging and discharging circuit unit 231 is a circuit for transferring the energy input to the charging and discharging power terminals 273 and 274 to the cell 210 or transmitting the energy stored in the cell 210 to the charging and discharging power terminals 273 and 274 .

The charge / discharge control unit 233 controls the charge / discharge circuit unit 231 to individually charge or discharge the cells 210. [ That is, the charge / discharge controller 233 performs cell balancing of the cell 210. At this time, the charge / discharge control unit 233 controls the charge / discharge circuit unit 231 based on the control signal received from the wireless communication module 235.

The charge / discharge control unit 233 transfers the state information of the cell 210 to the wireless communication module 235.

The wireless communication module 235 transfers the control signal received from the wireless battery management device 300 to the charge / discharge control unit 233. The wireless communication module 235 transmits the status information of the cell 210 received from the charging and discharging control unit 233 to the wireless battery management device 300. [

The wireless communication module 235 may be a communication module of various types, for example, Bluetooth, Zigbee, etc.

3 is a circuit diagram of a cell module according to an embodiment of the present invention.

3, the charge / discharge circuit unit 231 of the cell module 200 may be configured in various ways. For example, the charge / discharge circuit portion 231a includes a switch 400, a current sensor 420, and a DC / DC converter 500. Here, the DC / DC converter 500 may be a bidirectional DC / DC converter or a unidirectional DC / DC converter.

One side of the DC / DC converter 500 is connected to charge / discharge power terminals 273 and 274, and the other side is connected to the cell 210.

The switch 400 may be located between the cell 210 and the DC / DC converter 500.

The charge / discharge control unit 233 is connected to charge / discharge power terminals 273 and 274 to receive power.

Discharge control unit 233 can control the DC / DC converter 500 and the switch 400 based on the control signal transmitted from the wireless communication module 235. [ At this time, the wireless communication module 235 receives a control signal from the wireless battery management device 300. [

The charge / discharge controller 233 controls the DC / DC converter 500 to individually charge or discharge the cell 210. The DC / DC converter 500 can operate as a CC / CV charger.

Discharge control unit 233 can control the switch 400 to interrupt the power consumption. That is, the charge / discharge control unit 233 opens the switch 400 so that the cell module 200 does not consume unnecessary power. In addition, when the power is not supplied through the charge / discharge power terminals 273 and 274, the charge / discharge control unit 233 opens the switch 400 to prevent unnecessary power consumption.

The charging / discharging controller 233 senses the charging current of the cell 210 through the current sensor 420.

The charge / discharge control unit 233 senses the temperature of the cell 210 through the temperature sensor 290.

Discharge control unit 233 transfers the status information of the cell 210 collected from the current sensor 420 and the temperature sensor 290 to the wireless communication module 235. [ The wireless communication module 235 transmits the state information of the cell 210 to the wireless battery management device 300.

4 is a circuit diagram of a cell module according to another embodiment of the present invention.

Referring to Fig. 4, the charge / discharge circuit portion 231b is formed of an AC-insulated circuit.

The charge / discharge circuit 231b includes a switch 400, a current sensor 420, a bidirectional DC / DC converter 510, a bidirectional DC / AC converter 520, and a transformer 600.

The transformer 600 is located between the bidirectional DC / AC converter 520 and the charge / discharge power terminals 273 and 274 to insulate the power source from the cell.

One side of bidirectional DC / AC converter 520 is connected to transformer 600 and the other side is connected to bidirectional DC / DC converter 510.

The switch 400 may be located between the cell 210 and the bi-directional DC / AC converter 520.

Discharge control unit 233 controls the switch 400, the bidirectional DC / DC converter 510, and the bidirectional DC / AC converter 520 to charge and discharge the cell 210. FIG. At this time, the charging / discharging control unit 233 can control based on the control signal transmitted from the wireless communication module 235. The wireless communication module 235 receives a control signal from the wireless battery management device 300.

5 is a circuit diagram of a cell module according to another embodiment of the present invention.

Referring to FIG. 5, the charge / discharge circuit portion 231c is formed of a DC insulation type circuit.

The charge and discharge circuit portion 231c includes a switch 400, a current sensor 420, cell-side converters 510 and 520, power-source-side converters 530 and 540, and a transformer 600. The cell-side converters 510 and 520 are composed of a bidirectional DC / DC converter 510 and a bidirectional DC / AC converter 520. The power source side converters 530 and 540 are composed of a bidirectional AC / DC converter 530 and a bidirectional DC / DC converter 540.

The transformer 600 is disposed between the cell-side converters 510 and 520 and the power-source-side converters 530 and 540 to insulate the power source from the cell.

One side of the power source side converters 530 and 540 is connected to charge / discharge power terminals 273 and 274, and the other side is connected to the transformer 600.

One side of the cell-side converters 510 and 520 is connected to the transformer 600 and the other side is connected to the cell 210.

The switch 400 may be located between the cell 210 and the bi-directional DC / DC converter 510.

The charge / discharge control unit 233 controls the switch 400, the cell-side converters 510 and 520, and the power-source-side converters 530 and 540 to charge and discharge the cell 210. Discharge control unit 233 can control based on the control signal transmitted from the wireless communication module 235. [ At this time, the wireless communication module 235 receives a control signal from the wireless battery management device 300. [

6 and 7 are circuit diagrams of a battery pack according to an embodiment of the present invention.

Referring to FIGS. 6 and 7, the battery packs 100a and 100b include a plurality of cell modules 200. The battery packs 100a and 100b further include switches 750 and 760, a wireless switch control device 770, and a power supply 780.

The plurality of cell modules 200 are connected in series to form a cell module stack. The anode of the cell module stack is connected to the battery pack anode terminal 710, and the cathode of the cell module stack is connected to the battery pack cathode terminal 720.

A plurality of cell modules 200 are connected in parallel to a charge / discharge power terminal for individual charging. 6, each cell module 200 may have a charge / discharge power terminal connected to the battery pack positive terminal 710 and the battery pack negative terminal 720, respectively. Alternatively, as shown in FIG. 7, each cell module 200 may be connected to a separate charge / discharge power terminal 730, 740.

The switch 750 connects or disconnects the cell module stack with the battery pack positive terminal 710 / battery pack negative terminal 720.

The switch 760 connects or disconnects the cell module and the charge / discharge power supply terminals 730 and 740.

The wireless switch control device 770 wirelessly communicates with the wireless battery management device 300. The wireless switch control device 770 controls ON / OFF of the switches 750 and 760 in accordance with the control signal of the wireless battery management device 300. The wireless battery management device 300 collects status information of the cell from each cell module 200. The wireless battery management device 300 controls the switches 750 and 760 based on the status information of each cell.

For example, when the wireless battery management device 300 charges the external charger, the wireless switch control device 770 monitors whether the voltage of the cell modules 200 reaches the reference voltage. When the reference voltage is reached, the wireless battery management device 300 opens the switch 750 to block rapid charging by the external charger. Then, the wireless battery management device 300 closes the switch 760 and performs CC / CV full charging using the charge / discharge circuit 231 of each cell module 200 individually. The reference voltage varies depending on the cell to be used, but may be about 4.1 V for the lithium polymer battery. At this time, the wireless battery management device 300 can rapidly charge about 90% to 95% of the cell capacity, and the remaining capacity can be separately CC / CV charged through the charge / discharge circuit unit 231 of each cell module.

The battery packs 100a and 100b may further include a system switch 790 for connecting or disconnecting power to the power supply 780. When the system switch 790 is closed, power is supplied to the power supply 780 so that the wireless switch control apparatus 770 operates. When the system switch 790 is opened, the power supply to the power supply 780 is cut off, so that the power consumption of the battery pack 100 can be reduced.

8 is a block diagram of a battery energy storage device according to another embodiment of the present invention.

Referring to FIG. 8, the battery energy storage device 1000 includes a plurality of battery packs 1100-1, 1100-2, ..., 1100-M, a plurality of battery packs 1100-1, 1100-2,. A plurality of slave wireless battery management devices 1200-1, 1200-2, ..., and 1200-M that control charging and discharging of the master wireless battery management device 1300 ).

The master wireless battery management device 1300 transmits control signals to the slave wireless battery management devices 1200-1, 1200-2, ..., and 1200-M, or receives various status information. At this time, the master wireless battery management device 1300 and the slave wireless battery management devices 1200-1, 1200-2, ..., and 1200-M wirelessly communicate. Each slave wireless battery management device has unique identification information so that the master wireless battery management device 1300 can distinguish a plurality of slave wireless battery management devices based on the identification information.

9 is an assembled view of a cell module according to an embodiment of the present invention.

Referring to FIG. 9, the cell module 200 can be manufactured in various forms.

For example, the cell module 200 may include a case containing the cell 210 and a case containing the circuit unit 230.

Terminals 271, 272, 273, and 274 for external connection are exposed to the outside of the circuit unit 230. The antenna 250 of the wireless communication module 235 is exposed to the outside of the circuit unit 230.

10 is an assembled view of a battery pack according to an embodiment of the present invention.

Referring to FIG. 10, a plurality of cell modules 200 are stacked and assembled in the battery pack 100.

A plurality of cell modules 200 are connected in series to the positive terminal 271 and the negative terminal 272. The plurality of cell modules 200 are connected to charge / discharge power terminals 273 and 274 in parallel.

At this time, in order to facilitate the series connection to the positive electrode terminal 271 and the negative electrode terminal 272, the positions of the negative electrode and the positive electrode of the cell module 200 stacked up and down can be reversed. Or the cell module 200 of the first type and the cell module 200 of the second type that are opposite in position between the cathode and the anode can be manufactured.

Although the charging and discharging have been described above, the wireless battery management device can perform cell formation while communicating wirelessly with the cell module or the battery pack.

As described above, according to the embodiment of the present invention, since the battery management device and the battery pack communicate wirelessly, complicated wiring can be reduced. According to the embodiment of the present invention, the battery pack can be easily assembled, and the single cell module can be easily replaced.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It belongs to the scope of right.

Claims (12)

delete delete delete delete delete delete A battery energy storage device for controlling charging and discharging in a radio control manner,
A battery pack for charging or discharging cells of the plurality of cell modules based on at least one control signal wirelessly transmitted, and
Receiving the state information of each cell wirelessly transmitted from each cell module, generating at least one control signal based on the received state information, and transmitting at least one control signal, And a battery management device for wirelessly transmitting the data to the battery pack,
The battery pack
A cell module stack in which cells of a plurality of cell modules are connected in series,
A first switch located between the anode of the cell module stack and the battery pack positive terminal,
A second switch positioned between each cell module and a power terminal for individual charging and discharging of each cell module, and
And a wireless switch control device that receives a control signal wirelessly transmitted from the battery management device and controls the first switch and the second switch based on a first control signal among the received control signals,
Each cell module
A cell in which energy is stored,
A wireless communication module for wirelessly communicating with the battery management device and receiving a second control signal among control signals wirelessly transmitted by the battery management device,
A charge and discharge circuit unit for transferring the energy input from the charge and discharge power source terminal to the cell based on the third control signal and transmitting the energy stored in the cell to the charge and discharge power source terminal based on the fourth control signal,
A charge / discharge control unit for receiving the second control signal from the wireless communication module and generating the third control signal and / or the fourth control signal based on the second control signal to control the charge / discharge circuit unit Includes battery energy storage. 8. The method of claim 7,
The battery management apparatus
When the battery pack is charged using the battery pack positive terminal and the external charger connected to the battery pack negative terminal, the first switch is closed to quickly charge the plurality of cell modules, and a plurality And generates and transmits to the wireless switch control device the first control signal to monitor whether the voltage of the cell module reaches the reference voltage and, when the reference voltage is reached, charge each cell module individually. 9. The method of claim 8,
Wherein the first control signal is a signal to open the first switch and command the second switch to close. 8. The method of claim 7,
The charge / discharge circuit unit includes a DC / DC converter,
Wherein one side of the DC / DC converter is connected to a cell of the corresponding cell module, and the other side of the DC / DC converter is connected to the charge / discharge power terminal. 8. The method of claim 7,
The charge / discharge circuit portion includes a bidirectional DC / DC converter, a bidirectional DC / AC converter, and a transformer,
One side of the bidirectional DC / DC converter is connected to a cell of the corresponding cell module, the other side of the bidirectional DC / DC converter is connected to one side of the bidirectional DC /
Wherein the other side of the bidirectional DC / AC converter is connected to one side of the transformer and the other side of the transformer is connected to the charge / discharge power terminal. 8. The method of claim 7,
Wherein the charge / discharge circuit portion further comprises a bidirectional AC / DC converter and a bidirectional DC / DC converter between the transformer and the charge / discharge power terminal.

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