KR101028756B1 - Power input control circuit for battery management system - Google Patents

Abstract

The present invention relates to a power input control circuit of a battery management system. The power input control circuit of the battery management system 100 according to an embodiment of the present invention can stably configure a connection between a battery cell and a battery management system. This allows more precise control of the power input of the battery management system.

Battery management system, power input, control

Description

Power input control circuit for battery management system

The present invention relates to a battery management system, and more particularly, to a power input control circuit of a battery management system that can be used in an automobile utilizing electrical energy.

Automobiles using internal combustion engines that use gasoline or heavy oil as their main fuels have serious effects on pollution, such as air pollution. Therefore, in recent years, in order to reduce the occurrence of pollution, much efforts have been made in the development of electric vehicles or hybrid vehicles.

An electric vehicle is a vehicle using a battery engine operated by electric energy output from a battery. Such an electric vehicle uses no battery as a main power source because a plurality of secondary cells capable of charging and discharging are used as a pack has no exhaust gas and has a very small noise.

On the other hand, a hybrid vehicle is a vehicle of an intermediate stage between an automobile using an internal combustion engine and an electric vehicle, and a vehicle using two or more power sources, such as an internal combustion engine and a battery engine. At present, a hybrid vehicle of a hybrid type has been developed, such as using a fuel cell that directly generates an electric energy by chemical reaction while continuously supplying an internal combustion engine and hydrogen and oxygen, or uses a battery and a fuel cell.

As such, the vehicle using electric energy has a direct effect on the performance of the battery. Therefore, the performance of each battery cell must be excellent, and each battery cell is measured by measuring the voltage of each battery cell and the voltage and current of the entire battery. The battery management system (BMS) that can efficiently manage the charging and discharging of the (BMS) is urgently required.

The present invention relates to a power input control of a battery management system, which can stably configure a connection between a battery cell and a battery management system, and to control power input of a battery management system that can more accurately control a power input of a battery management system. To provide a circuit.

In order to achieve the above technical problem, a power input control circuit of a battery management system (Battery management system) that can be used in a vehicle using electrical energy according to an embodiment of the present invention and the first terminal connected to the positive side of the battery; A first connector including a second terminal connected to the negative side of the battery, and receiving a signal for sensing power supply to the battery management system and a voltage of the battery through the first terminal and the second terminal; A shunt resistor connected between the negative side of the battery, the negative side of the load and a battery node of the battery management system; A second connector having a first terminal connected to one terminal of the shunt resistor to receive a signal for sensing the battery side current, and a second terminal connected to the other terminal of the shunt resistor; And a resistor connected between the first terminal of the first connector and the positive side of the battery.

Preferably, the power input control circuit is characterized in that the positive terminal of the charger for charging the battery is connected to the positive side of the battery, further comprises a charger node for connecting with the negative terminal of the charger.

Advantageously, said power input circuit further comprises a fuse for interrupting power supply and voltage transfer from said first terminal of said first connector to said battery management system.

The power input control circuit of the battery management system 100 according to an embodiment of the present invention can stably configure a connection between the battery cell and the battery management system, and more accurately control the power input of the battery management system.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description, only parts necessary for understanding the operation according to the present invention will be described, and descriptions of other parts may be omitted so as not to distract from the gist of the present invention.

In addition, terms and words used in the following description and claims should not be construed to be limited to ordinary or dictionary meanings, but are to be construed in a manner consistent with the technical idea of the present invention As well as the concept.

1 is a schematic block diagram of a battery management system 100 according to an embodiment of the present invention.

Referring to FIG. 1, the battery management system 100 is connected to a battery cell 200, a load, and a charger. A resistor 201 is connected between the battery management system 100 and the positive side of the battery cell 200, and a shunt resistor 202 is connected between the negative side of the battery cell 200. Here, the shunt resistor 202 functions to sense current. The fuse 203 is connected between the positive side of the battery cell 200 and the positive terminal of the load. Here, the battery cell 200 is composed of a lithium-ion polymer battery, and is a battery module consisting of 13 battery cells. Each battery cell is 4.3V per cell and the total voltage is 55.9V.

The battery management system 100 may measure the remaining capacity, current, voltage, and battery temperature of the battery. In addition, the battery management system 100 includes a driver for driving a 10 point LED for a state of charge (SOC) display and performs overcharge protection and cell balancing functions.

The battery management system 100 may include a micro process unit 101, a residual capacity detector, a current detector, a voltage detector, a battery state detector 102 including a temperature detector, a cell balancer 103, an overcharge protector 104, The power supply unit 105, the input control unit 106, the output control unit 107, the SOC display unit 108, and the communication unit 109 are included.

The micro process unit 101 controls the overall operation of the battery management system 100. The micro process unit 101 outputs control signals for controlling each configuration module of the battery management system 100 and controls each configuration module according to a signal input through an external input means. For example, the voltage of the battery cell 200 is sensed to turn on / off the operation of the overcharge protection unit 104 by comparing with a predetermined reference voltage, and the cell balancing operation is turned on / off by measuring the cell voltage of the battery cell 200. The charging and discharging of the battery cell 200 is controlled by turning off. In addition, the SOC display unit 108 is controlled according to an SOC display command input from the outside to display the SOC.

The battery state detector 102 detects the remaining capacity, current, voltage, and temperature of the battery. Here, residual capacity, voltage, and temperature detection is performed for each battery cell, that is, 13 battery cells, and the current senses the flow on the high current path through the shunt resistor 202.

In order to detect the temperature, the temperature detector includes a connector for connecting 13 thermistors to the respective battery cells Cell 1, Cell 2,... Cell 13 to detect each cell temperature.

For the cell voltage detection, the cell voltage detector is configured at each of the battery cells (Cell 1, Cell 2, .... Cell 13) at the positive side of Cell 1, the negative side of Cell 1 and the positive side of Cell2. Measure the voltage on cell 1. The cell voltage detector includes a connector using 14 pins connected to the battery cells 200 for cell voltage measurement to detect each cell voltage. The detected cell voltage is used for overcharge protection, overdischarge protection, and cell balancing.

The cell balancing unit 103 balances the state of charge of each battery cell. The cells with a relatively high state of charge are discharged and the cells with a relatively low state of charge are charged. Such a cell balancing operation can make the charging voltage of each cell uniform by sensing the voltage of each battery cell and discharging the cells above the reference voltage.

The overcharge protection unit 104 sets the overcharge protection flag when the charging voltage of the battery cell 200 is equal to or greater than a predetermined voltage, for example, 55.9 V (4.3 V / cell), and the MPU 101 sets the overcharge protection flag. Therefore, a control signal is sent to prohibit further charging and activates the protection circuit. Here, the control signal is a charge blocking signal, which blocks the charging FET located in the large current path to stop charging. The overcharge protection unit 104 may set an overcharge protection flag by detecting not only a cell voltage but also a current and a temperature.

The power supply unit 105 receives power from the battery cell 200. Here, the battery management system 100 receives power from the battery cell 200 through a 2-pin connector, a fuse is connected to the battery management system 100, and is connected between the positive terminal of the battery cell 200 and the connector. A resistor of a predetermined size is connected. Optionally, a DC-DC converter (not shown) may be used to use the voltage from the battery cell 200 as an internal power supply (VCC).

The input control unit 106 transmits an input signal from the outside, for example, an ACC key of the vehicle or an input signal of the SOC display switch to the battery management system 100.

The output control unit 107 functions to transmit a control signal from the micro process unit 101 to external protection circuits. The output control unit 107 transmits a control signal from the microprocessor unit 101, for example, an overcharge protection circuit operation signal, a cell balancing circuit operation signal, and an over discharge protection circuit operation signal to external protection circuits. Here, the output control unit 107 may include a circuit for preventing a malfunction of each of the protection circuits, for example, a circuit including a transistor, an optocoupler, and a diode.

The SOC display unit 108 controls to display the current charging state of the battery cell 200 as 10 LEDs according to an external input signal, that is, an SOC display switch input signal. The SOC display 108 includes an LED driver for driving the LEDs. The SOC display 108 is connected to an LED connected to the battery management system 100 through a connector consisting of 14 pins. Ten pins are connected to ten diodes, and the output signal through the ten pins, the LED control signal, is an open collector signal. Internal power is supplied to the LEDs through the two pins, which are grounded. Alternatively, the external power supply Vsupply may be supplied to the LED without using the internal power supply VCC. Here, one LED lighting means 10% SOC, and one LED lighting is made for SOC of 5% or more. Thus, for 36% SOC, four LEDs are controlled to turn on. Here, in the SOC display, when a user presses an external SOC display switch, an input signal corresponding thereto is input to the battery management system 100 through an input connector. This will be described later with reference to FIG. 2.

The communication unit 109 is a module for communicating between components of the battery management system 100 or between the battery management system 100 and an external device. For example, the communication unit 109 may be an RS232C interface.

FIG. 2 is a schematic circuit diagram of a connection relationship between a battery cell 200 and a battery management system 100 and a power input control part shown in FIG. 1.

Referring to FIG. 2, the battery management system 100 includes a first connector 121, a second connector 122, a battery node 123, a charger node 124, and a fuse 125.

The first connector 121 connects the battery cell 200 and the battery management system 100 to supply power to the battery management system 100 and to perform voltage sensing of the battery cell 200. The first terminal of the first connector is connected with the positive side of the battery cell 200, and the second terminal is connected with the negative side of the battery cell 200. Here, a resistor of a predetermined size is connected between the first terminal and the positive side of the battery cell 200. Preferably, the resistor has a size of 20 ohms / 0.5 watts, which prevents direct power to the battery management system 100 and serves as a pre-charge.

A shunt resistor 202 is connected between the battery cell 200 and the battery management system 100. One side of the shunt resistor is connected to the negative side of the battery cell 200, and is connected to the battery node 123 of the battery management system 100 to sense a current on the high current path. In general, a shunt resistor is a device that joins copper and manganese with a continuous electron beam, and is used to measure a fine current value by using different resistance values at both ends of the device.

First and second terminals of the second connector 122 are connected to one terminal and the other terminal of the shunt resistor 202. The current value sensed through the shunt resistor 202 is provided to the micro process unit 101 of the battery management system 100 via the second connector 122.

The battery node 123 is connected to the other terminal of the shunt resistor 202, and the charger node 124 is connected to the negative terminal of the charger.

The fuse 125 is connected to the first terminal of the first connector 121 to block power supply and voltage transfer from the first terminal to the battery management system 100 at the time of overvoltage supply.

The fuse 203 is located on the large current path to block excessive current when flowing to the load.

So far I looked at the center of the preferred embodiment for the present invention. Those skilled in the art will understand that the present invention can be embodied in a modified form without departing from the essential characteristics of the present invention. Therefore, the disclosed embodiments should be considered in descriptive sense only and not for purposes of limitation. The scope of the present invention is shown not in the above description but in the claims, and all differences within the scope should be construed as being included in the present invention.

1 is a schematic block diagram of a battery management system 100 according to an embodiment of the present invention.

FIG. 2 is a circuit diagram illustrating a connection relationship between the battery cell 200 and the battery management system 100 and power input control shown in FIG. 1.

<Description of the symbols for the main parts of the drawings>

100: battery management system (BMS) 101: micro process unit (MPU)

102: battery state detection unit 103: cell balancing unit

104: overcharge protection unit 106: input control unit

107: output control unit 108: SOC display unit

109: communication unit 200: battery cell

201: resistance 202: shunt resistance

203: fuse

Claims (3)

In the power input control circuit of the battery management system (Battery management system) that can be used in a vehicle using electric energy, A first terminal connected to the positive side of the battery and a second terminal connected to the negative side of the battery, the power supply to the battery management system and the voltage of the battery through the first terminal and the second terminal; A first connector to which a signal for detecting a signal is input; A shunt resistor connected between the negative side of the battery, the negative side of the load and a battery node of the battery management system; A second connector having a first terminal connected to one terminal of the shunt resistor to receive a signal for sensing the battery side current, and a second terminal connected to the other terminal of the shunt resistor; And And a resistor connected between the first terminal of the first connector and the positive side of the battery. The method of claim 1, The positive terminal of the charger for charging the battery is connected to the positive side of the battery, further comprising a charger node for connecting to the negative terminal of the charger. The method of claim 1, And a fuse for interrupting power supply and voltage transfer from the first terminal of the first connector to the battery management system.

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