KR20150077771A - Battery management device and power supplying system including the same - Google Patents

Abstract

The present invention has the purpose to provide a battery management device to perform real-time monitoring with regard to batteries and to be capable of reducing safety problems generated from high voltage from the batteries. Another purpose of the present invention is to provide a power supplying system capable of reducing the safety problems generated from high voltage from the batteries. The battery management device (3) is configured to detect a current state of an electronic device, and configured to control power supply from a battery device (5) to a load (4) of the electronic device. The battery device (5) includes a plurality of battery units (51) which are electrically connected. If it is detected that the electronic device is in an unusual state, the battery management device (3) incapacitates the battery units (51) to stop the power supply to the load (4).

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a battery management device and a power supply system including the battery management device,

The present invention relates to a battery management device and a power supply system including the battery management device.

In electric vehicle applications, several battery units are usually connected in series to provide the required high voltage. However, in order to prevent damage to battery units due to performance differences, a battery management system is adopted to manage and monitor the charge-discharge operations of the battery units.

Referring to Figure 1, a conventional battery management system 12 is adapted to be used in the power supply 1. The power supply device 1 is used to supply power to the load 2 and includes a plurality of battery units 11, two main switches 13, and a current sensor 15. Each of the main switches 13 is electrically connected to the series-connected battery units 11 and the load 2. Each of the battery units 11 includes a battery 111 and a sensor 112 adapted to sense a voltage, a temperature, and / or a current of the battery 111.

The battery management system 12 is electrically connected to the sensors 12, the current sensor 15 and the main switches 13 and to the main switches 13 to make or break an electrical connection. And performs real-time monitoring of the voltage, temperature, and current of each battery 111 during the charging operation.

When the power supply device 1 is abnormal or needs to be repaired, the main switches 13 should be switched off, but the series-connected battery units 11 will still be able to output a high voltage, Resulting in safety problems. In U.S. Patent No. 7,990,105 B2, a safety plug is provided to isolate each of the battery units 11 during maintenance, for the purpose of ensuring human safety.

However, when the power supply device 1 is used in an electric vehicle (e.g., an automobile or a boat), it may be subject to electricity leakage, soaking in water, or shock. The safety plug can not provide protection in such situations.

U.S. Patent No. 7990105 B2

It is therefore an object of the present invention to provide a battery management device that can perform real-time monitoring with respect to batteries and reduce safety problems arising from the high voltages of the batteries.

It is another object of the present invention to provide a power supply system that can reduce safety problems arising from high voltages of batteries.

It is an object of the present invention to provide a battery management device that can perform real-time monitoring with respect to batteries and reduce safety problems arising from the high voltage of the batteries.

According to one aspect of the present invention, there is provided a battery management device for controlling power supply from a battery device to a load of an electric device. The battery device includes a plurality of electrically connected battery units. Each of the battery units is independently controllable to switch between an output enable state and an output disable state. The battery management device comprises:

A device sensor configured to detect a current state of the electric device and configured to output a detection signal corresponding to a current state of the electric device;

Wherein the sensor is configured to store a predetermined threshold and is coupled to the instrument sensor for receiving the detection signal and is configured to compare the detection signal with the predetermined threshold, And outputting a device status signal indicating whether the electric device is in a normal state or an abnormal state according to a result of comparison between the values; And

And electrically connected to each of the battery units, electrically connected to the determination module for receiving the instrument status signal, and configured to switch each of the battery units to an output disabled state, And stops the supply of power to the load when the device state signal indicates that the device is in a state.

It is another object of the present invention to provide a power supply system that can reduce safety problems arising from high voltages of batteries.

According to another aspect of the present invention, a power supply system for an electric appliance is provided. The electric device includes a load. The power supply system comprising:

A plurality of battery units electrically connected to supply power to the load, each of the battery units being independently controllable to switch between an output enable state and an output disable state; And

And a battery management device according to the present invention.

According to another aspect of the present invention, an electric device includes a load and a power supply system of the present invention.

The effects of the present invention are specified separately in the relevant portions of this specification.

Other features and advantages of the present invention will become apparent from the following detailed description of the preferred embodiments with reference to the accompanying drawings.
1 is a block diagram illustrating a power supply device including a conventional battery management system.
2 is a block diagram showing a preferred embodiment of an electric device according to the present invention.
3 is a block diagram showing a control module of the battery management device of the preferred embodiment.

2, a preferred embodiment of an electric device according to the present invention is shown to include a load 4, a power supply system 8, and a load driver 7. [

The load operates using a high voltage direct current (DC) voltage. The power supply system 8 is configured to provide a DC voltage to the load 4 and includes a battery 5 and a battery management device 3.

In this embodiment, the battery device 5 includes a plurality of battery units 51 electrically connected in series and two main switches 52. Each of the battery units 51 includes a battery 511, an isolation switch 512 electrically connected in series to the battery 511, and a battery sensor 513. The battery 511 may be comprised of several lithium manganese battery cells, lithium iron battery cells, or other types of battery cells connected in series and / or in parallel. The battery sensor 513 senses the state of the battery 511 (for example, the voltage, current, and / or temperature of the battery 511) 51) is in a steady state or in an abnormal state.

Since the batteries 511 are isolated from each other by using the isolation switches 512 although the battery units 51 are connected in series, there is no gap between the batteries 511 of the battery units 51 There is no direct electrical connection. Each of the battery units 51 can be independently controlled to switch between the output enable state and the output disable state through the control of the isolation switch 512 of the battery unit

Each of the main switches 52 is electrically connected between the series connected battery units 51 and the load 4. In other embodiments, the battery device 5 may include only one main switch 52.

The battery management device 3 includes a device sensor 33, a determination module 32, a control module 31, and an activation switch 6.

The device sensor 33 is adapted to detect the current state of the electric device and to output a detection signal corresponding to the current state of the electric device. In particular, the instrument sensor 33 detects a voltage state of the battery device 5, including a voltage / current converter, an accelerometer, a hygrometer, and the like. A temperature state of the battery device 5; A discharge current state of the battery device 5; A load state of the electric device; Whether or not the electric device has undergone a short circuit; Whether or not the electric device has undergone electric leakage; Whether or not the electric device is impacted; The humidity conditions of the electrical equipment, and the like. In this embodiment, the detection signal output by the device sensor 33 has a detection value corresponding to the current state of the electric device.

The discrimination module 32 stores a predetermined threshold value and is connected to the device sensor 33 for receiving the detection signal and compares the detection signal with the predetermined threshold value, And outputs the device state signal according to a result of the comparison between the detection signal and the predetermined threshold value. The device state signal indicates whether the electric device is in a normal state or an abnormal state. The abnormal state may include an overvoltage condition, an undervoltage condition, an overload condition, a short-circuit condition, an electrical leakage condition, an impact condition, a humid condition, or a wet condition, May be distinguished by the discrimination module 32 using a signal.

The control module 31 is electrically connected to the discrimination module 32 to receive the instrument status signal and is connected to the battery sensor 513 of each of the battery units 51 to receive the battery status signal. And controls the isolation switch 512 of each of the main switches 512 and the battery units 51 to detect the device status signal from the determination module 32 and the battery status information To make or break an electrical connection in accordance with the battery status signals from the sensors 513. In detail, the control module 31 controls the main switch 52 to cut off the electrical connection between the battery units 51 and the load 4, and the battery units 51 (I.e., each of the battery units 51 is switched to an inoperable state) by controlling each of the isolation switches 512 so that the electric device is in an abnormal state (4) when the battery status signal of one of the battery units (51) indicates that the device status signal is displayed and / or that the corresponding battery (51) is in an abnormal state Stop. In this state, there is no electrical connection between any two battery units of the battery units 51, so that no high voltage is provided to the electric device.

The activation switch 6 comprises a first terminal 61 for receiving a bias voltage Vcc, a second terminal 62 electrically connected to the control module 31 and a control terminal 63). The activation switch 6 is controlled by the activation signal to make or break an electrical connection between the first terminal 61 and the second terminal 62 of the activation switch 6, And controls supply of the bias voltage (Vcc) to the control module (31).

Referring to FIG. 3, in this embodiment, the control module 31 includes a logic unit 312 and a controller 311. The logic unit 312 is coupled to the determination module 32 to receive the instrument status signal and is coupled to the activation switch 6 to receive the bias voltage Vcc, ) Signal to the load driver 7 for receiving the signal. The controller 311 is connected to the isolation switch 512 of each of the logic unit 312, the main switches 52 and the battery units 51.

The logic unit 311 is configured such that when the logic unit 312 receives one of the enable signal and the bias voltage Vcc and receives the instrument status signal indicating that the electrical apparatus is in a steady state, , And to output an operation signal to the controller 311. The controller 311 controls the main switches 52 in response to the operation signal to make an electrical connection and controls the isolation switch 512 of each of the battery units 51 to electrically (I.e., each of the battery units 51 is switched to the output enable state). Otherwise, the controller 311 controls the main switches 52 to block the electrical connection and controls the isolation switch 512 of each of the battery units 51 to block the electrical connection (I.e., each of the battery units 51 is switched to the output disable state).

When the electric device is turned on, the activation signal is provided to the activation switch 6 so that the bias voltage Vcc is transmitted to the logic unit 312. At this point, when the instrument status signal indicates that the electrical apparatus is in a steady state, the logic unit 312 outputs the operation signal to the controller 312, The main switch 52 and the isolation switch 512 of each of the battery units 51 to make an electrical connection so that the battery device 5 can be operated normally for the normal operation of the electric device And to output power to the load (4). After the battery device 5 becomes able to output electric power, the load driver 7 receives electric power from the battery device 5 and outputs the enable signal. It should be noted that the load driver 7 is used for driving the function of the load 4 and is not designed for battery management. With such a design, the activation switch 6 need not always be closed after the electric device is turned on, and the battery device 5 can still normally supply power. At the same time, the controller 311 will be able to send messages to the load driver 7 for monitoring purposes.

In summary, when the electric device is in an abnormal condition or requires repair, the battery management device 3 operates to isolate the battery units 51 to prevent a high voltage from being output, To ensure the safety of people.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is intended that the present invention not be limited to the disclosed embodiment, but that all such modifications and equivalent arrangements as various arrangements included within the spirit and scope of the broadest interpretation It is to be understood that they are intended to cover the various arrangements as described above.

The present invention can be used to manage battery devices used in places such as electric vehicles, and can be used to provide a power supply system including such battery management devices.

Claims (20)

A battery management device (3) for controlling power supply from a battery device (5) to a load (4) of an electric device,
The battery device (5) includes a plurality of electrically connected battery units (51), each of the battery units (51) being independently controllable to switch between an output enable state and an output disable state, The management device 3:
A device sensor (33) configured to detect a current state of the electric device and configured to output a detection signal corresponding to the current state of the electric device;
Is configured to store a predetermined threshold and is coupled to the instrument sensor (33) for receiving the detection signal and is configured to compare the detection signal with the predetermined threshold, A discrimination module (32) configured to output an instrument state signal indicating whether the electric device is in a normal state or an abnormal state according to a result of comparison between predetermined threshold values; And
And is electrically connected to each of the battery units 51 and is electrically connected to the discrimination module 32 to receive the device status signal and switches each of the battery units 51 to an output disabled state And a control module (31) for stopping power supply to the load (4) when the device status signal indicates that the electric device is in an abnormal state. The method according to claim 1,
Wherein the detection signal output by the device sensor (33) has a detection value, and the predetermined threshold value stored by the determination module (32) is a predetermined value. The method according to claim 1,
The battery device (5) further includes a main switch (52) electrically connected between the battery units (51) and the load (4)
The control module 31 is further configured to control the main switch 52 to break the electrical connection between the battery units 51 and the load 4, And stops power supply to the load (4) when the device state signal indicates that the device is in an abnormal state. The method according to claim 1,
The battery device (5) further includes a main switch (52) electrically connected between the battery units (51) and the load (4)
The control module 31 is further arranged to receive a battery status signal from each of the battery units 51 indicating whether the battery unit 51 is in a normal state or an abnormal state,
The control module 31 controls the main switch 52 to shut off the electrical connection between the battery units 51 and the load and controls each of the battery units 51 in the output disable state And when the battery status signal of one of the battery units (51) indicates that one of the battery units (51) is in an abnormal state, the load (4 The power supply to the battery management device is stopped. The method according to claim 1,
Further comprising an activation switch (6)
The activation switch includes a first terminal 61 for receiving a bias voltage Vcc,
A second terminal 62 electrically connected to the control module 31, and
And a control terminal (63) for receiving an activation signal,
The activation switch 6 is controlled by the activation signal to make or break an electrical connection between the first terminal 61 and the second terminal 62 of the activation switch 6, And controls supply of bias voltage (Vcc) to the control module (31). 6. The method of claim 5,
The battery device (5) further includes a main switch (52) electrically connected between the battery units (51) and the load (4), and the control module (31)
A logic unit (312) coupled to the determination module (32) to receive the instrument status signal and to the activation switch (6) to receive a bias voltage (Vcc); And
And a controller (311) connected to the logic unit (312) and connected to the main switch (52) and the battery units (51), respectively,
The logic unit 311 is configured to output an operation signal to the controller 311 when the logic unit 312 receives the bias voltage Vcc and an instrument status signal indicating that the electrical apparatus is in a steady state ; And
The controller (311) controls the main switch (52) in response to an operation signal to make an electrical connection and to switch each of the battery units (51) to an output enable state. The method according to claim 1,
The current state of the electrical device detected by the device sensor 33 is:
The voltage state of the battery device 5;
A temperature state of the battery device 5;
A discharge current state of the battery device 5;
Load condition of electrical equipment;
Whether or not the electrical device underwent a short circuit;
Whether or not the electrical device has experienced electrical leakage;
Whether or not electrical equipment is impacted; And
The humidity condition of the electric device,
The battery management device comprising: A power supply system (8) for an electric appliance,
The electric device includes a load (4)
The power supply system (8) comprises:
And a plurality of battery units (51) electrically connected to supply power to the load (4), each of the battery units (51) being independently controllable to switch between an output enable state and an output disable state ; And
And a battery management device (3)
The battery management device (3) comprises:
A device sensor (33) configured to detect a current state of the electric device and configured to output a detection signal corresponding to the current state of the electric device;
Is configured to store a predetermined threshold and is coupled to the instrument sensor (33) for receiving the detection signal and is configured to compare the detection signal with the predetermined threshold, A discrimination module (32) configured to output an instrument state signal indicating whether the electric device is in a normal state or an abnormal state according to a result of comparison between predetermined threshold values; And
And is electrically connected to each of the battery units 51 and is electrically connected to the discrimination module 32 to receive the device status signal and switches each of the battery units 51 to an output disabled state And a control module (31) for stopping power supply to the load (4) when the instrument status signal indicates that the electrical machine is in an abnormal state. 9. The method of claim 8,
The battery units (51) are electrically connected in series. 9. The method of claim 8,
Wherein the detection signal output by the instrument sensor (33) has a detection value and the predetermined threshold value stored by the determination module (32) is a predetermined value. 9. The method of claim 8,
The battery device (5) further includes a main switch (52) electrically connected between the battery units (51) and the load (4)
The control module 31 is further configured to control the main switch 52 to break the electrical connection between the battery units 51 and the load 4, And stops power supply to the load (4) when the device state signal indicates that the device is in an abnormal state. 9. The method of claim 8,
The battery device (5) further includes a main switch (52) electrically connected between the battery units (51) and the load (4);
Each of the battery units 51 is configured to output a battery status signal indicating whether the battery unit 51 is in a normal state or an abnormal state; And
The control module 31 further receives the battery status signal from the battery units 51 and controls the main switch 52 to shut off the electrical connection between the battery units 51 and the load. And to switch each of the battery units 51 to the output disabled state so that the battery units 51 are informed that one of the battery units 51 is in an abnormal state, The power supply to the load (4) is stopped when the battery status signal of the one battery unit is displayed. 13. The method of claim 12,
Each of the battery units (51) comprises:
A battery 511;
An isolation switch 512 electrically connected in series to the battery 511 and electrically connected to the control module 31 and controlled by the control module to make or block an electrical connection; And
And a battery sensor (513) adapted to sense the state of the battery (511) and to output a battery state signal according to the state of the battery (511);
The battery 511 and the isolation switch 512 of each of the battery units 51 are electrically connected in series with at least one other battery unit of the battery units 51; And
Each of the battery units 51 is in an output-enabled state when its isolation switch 512 makes an electrical connection, and when its isolation switch 512 blocks an electrical connection, Power supply system. 14. The method of claim 13,
Wherein the state of the battery (511) sensed by the battery sensor (513) includes at least one of voltage, current and temperature of the battery (511). 9. The method of claim 8,
Further comprising an activation switch (6)
The activation switch includes a first terminal 61 for receiving a bias voltage Vcc,
A second terminal 62 electrically connected to the control module 31, and
And a control terminal (63) for receiving an activation signal,
The activation switch 6 is controlled by the activation signal to make or break an electrical connection between its first terminal 61 and the second terminal 62 so that the control module 31 (Vcc) supply to said power supply. 16. The method of claim 15,
The battery device (5) further includes a main switch (52) electrically connected between the battery units (51) and the load (4);
The control module (31) comprises:
A logic unit (312) coupled to the determination module (32) for receiving the instrument status signal and coupled to the activation switch (6) to receive the bias voltage (Vcc); And
And a controller (311) connected to the logic unit (312) and connected to the main switch (52) and the battery units (51), respectively,
The logic unit 311 is configured to output an operation signal to the controller 311 when the logic unit 312 receives the bias voltage Vcc and an instrument status signal indicating that the electrical apparatus is in a steady state ; And
The controller (311) controls the main switch (52) in response to an operation signal to make an electrical connection and to switch each of the battery units (51) to an output enable state. 17. The method of claim 16,
Further comprising a load driver (7) coupled to the control module (31) and configured to output an enable signal to the logic unit (312)
The logic unit 312 is adapted to receive the device status signal when the logic unit 312 receives one of the bias voltage Vcc and an enable signal and when the device status signal indicates that the device is in a steady state, And to output a signal to the controller (311). As electrical equipment:
Load 4; And
A power supply system (8)
The power supply system (8) comprises:
And a plurality of battery units (51) electrically connected to supply power to the load (4), each of the battery units (51) being independently controllable to switch between an output enable state and an output disable state ; And
And a battery management device (3)
The battery management device (3) comprises:
A device sensor (33) configured to detect a current state of the electric device and configured to output a detection signal corresponding to the current state of the electric device;
Is configured to store a predetermined threshold and is coupled to the instrument sensor (33) for receiving the detection signal and is configured to compare the detection signal with the predetermined threshold, A discrimination module (32) configured to output an instrument state signal indicating whether the electric device is in a normal state or an abnormal state according to a result of comparison between predetermined threshold values; And
And is electrically connected to each of the battery units 51 and is electrically connected to the discrimination module 32 to receive the device status signal and switches each of the battery units 51 to an output disabled state And a control module (31) for stopping the supply of power to the load (4) when the instrument status signal indicates that the electrical instrument is in an abnormal state. 19. The method of claim 18,
Further comprising a load driver (7) coupled to the control module (31) and configured to output an enable signal;
The battery management module (3) comprises:
Further comprising an activation switch (6)
The activation switch includes a first terminal 61 for receiving a bias voltage Vcc,
A second terminal 62 electrically connected to the control module 31, and
And a control terminal (63) for receiving an activation signal,
The activation switch 6 is controlled by the activation signal to make or break an electrical connection between the first terminal 61 and the second terminal 62 of the activation switch 6, Controlling the supply of the bias voltage (Vcc) to the control module (31);
The battery device (5) further includes a main switch (52) electrically connected between the battery units (51) and the load (4);
The control module 31 is configured to control the main switch 52 to make an electrical connection and the control module 31 receives one of the bias voltage Vcc and an enable signal, When the apparatus status signal indicating that the battery unit is in the normal state is received, and each of the battery units (51) is switched to the output enable state. 20. The method of claim 19,
When the control module 31 receives the bias voltage Vcc and the device state signal indicating that the electric device is in a steady state
After the main switch 52 is controlled to make an electrical connection and each of the battery units 51 is switched to the output enable state, the load driver 7 outputs the enable signal And to receive power from the battery device (5).

Images