KR100781794B1 - Battery Protection Circuit - Google Patents

Abstract

The present invention relates to a battery protection circuit, comprising: a protection IC for detecting overcharge and overdischarge and generating a blocking signal; A cutoff switch which cuts off a current according to a cutoff signal from the protection IC; A temperature detector for detecting an external temperature and adjusting and outputting an output signal according thereto; And a control switch for controlling the battery according to the output signal of the temperature detector so that the battery does not explode even when the external temperature rises, thereby extending the life of the battery. A battery protection circuit is proposed that can prevent deterioration.

Battery Protection Circuit, External Temperature, Thermistor

Description

Battery Protection Circuit {Battery Protection Circuit}

1 is a circuit diagram of a conventional battery protection circuit.

2 is a circuit diagram of a battery protection circuit according to an embodiment of the present invention.

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

21: protection IC 22: comparator

23: temperature detector

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a battery protection circuit, and more particularly, to a battery protection circuit capable of controlling a battery according to an external temperature as well as controlling charging and discharging of a battery used in various electronic products such as a mobile phone or a video camera.

Recently, batteries used in portable electronic devices have been downsized while their capacity has been increased. However, due to chemical properties, the battery does not function during overdischarge and there is a risk of battery expansion, explosion, and fire due to overcurrent due to overdischarge or short circuit. There is a need for measures to prevent safety accidents caused by overcurrent.

On the other hand, the lithium ion (Litium Ion) battery of the type of battery currently used in the battery voltage during charging, and when the overcharge state, the decomposition of the internal solvent occurs, there is a risk of ignition or rupture. On the other hand, nickel-cadmium (Ni-Cd) batteries or nickel-metal hydride (Ni-H) batteries have a memory effect, which extends battery life by charging them after the last discharge. However, a lithium ion battery has no memory effect, and when discharged to the end, a lithium ion battery may deteriorate a battery life due to deterioration of components of the battery. When the terminals are in contact with each other by a conductive material such as a noble metal or when a short occurs due to a failure of the connected device when the battery is stored or carried, an overcurrent flows and there is a risk of ignition or bursting of the battery. In order to solve this problem, the battery has been provided with a protection circuit for preventing a safety accident caused by overcharge, overdischarge, overcurrent.

An example of such a battery protection circuit is shown in FIG. 1. Referring to FIG. 1, the protection IC 11 may include a power supply terminal VDD, a ground terminal VSS, a discharge blocking signal output terminal DO for outputting an overdischarge and an overcurrent blocking signal, and a charge for outputting an overcharge blocking signal. A blocking signal output stage CO and an overcurrent sensing stage VM are provided. In addition, the protection IC 11 has an overcurrent cutoff value suitable for the characteristics of the portable electronic device at design time, and controls to block the discharge of the battery when a current higher than the set cutoff value is detected through the overcurrent detection stage (VM). Output the signal. The first field effect transistor (QFET) Q11 serves as a discharge control switch that operates in response to the overdischarge cutoff signal from the discharge cutoff signal output terminal DO of the protection IC 11 to block discharge of the battery. The second FET Q12 acts as a charge control switch to block charging of the battery by operating according to the overcharge blocking signal from the charge blocking signal output terminal CO of the protection IC 11. In addition, the first to third capacitors C11, C12, and C13 serve to prevent external noise and static electricity. In addition, the resistor R12 serves to prevent a reverse current to the protection IC 11 when a reverse power is applied to the protection circuit.

The operation of the conventional battery protection circuit configured as described above is as follows.

When handling a mobile communication terminal or a battery pack, if a short or overdischarge factor occurs in a terminal of a charger or a portable device, a voltage proportional to the current flowing by the internal resistance of the first FET Q11 and the second FET Q12. Is generated, and this voltage is sensed through the overcurrent sensing stage VM of the protection IC 11.

Subsequently, when the corresponding voltage is equal to or greater than the set overcurrent cutoff value, the protection IC 11 drops the signal of the discharge cutoff signal output terminal DO to a low level to turn off the first FET Q11 to block overdischarge of the battery.

In addition, during overcharging, a signal of the charge blocking signal output terminal CO is lowered to a low level to turn off the second FET Q12 to block overdischarge of the battery.

However, such a conventional battery protection circuit has a problem that the battery may explode because the battery cannot be controlled even if the external temperature rises excessively because the rise of the temperature cannot be detected.

SUMMARY OF THE INVENTION An object of the present invention is to provide a battery protection circuit that can prolong the life of a battery by preventing the battery from being exploded by detecting when the external temperature rises above a set temperature and controlling the battery.

Another object of the present invention is to control the output of the comparator in accordance with the voltage distributed between the variable resistance and the high resistance change the resistance value according to the external temperature, the switch is controlled according to the output of the comparator so that the external temperature is above the set temperature When rising to provide a battery protection circuit that can extend the life of the battery by preventing the battery by controlling the battery.

Battery protection circuit according to an embodiment of the present invention detects the overcharge and over-discharge protection IC for generating a blocking signal; A cutoff switch which cuts off a current according to a cutoff signal from the protection IC; A temperature detector for detecting an external temperature and adjusting and outputting an output signal according thereto; And a control switch for controlling the battery according to the output signal of the temperature detector.

The temperature detector includes a first voltage divider for distributing a voltage that varies with the external temperature; A second voltage divider for distributing a fixed voltage independent of the external temperature; And a comparator for inputting the voltages divided by the first and second voltage dividers, comparing them, and outputting the results.

The first voltage divider may include a fixed resistor having a fixed resistance value regardless of the external temperature; And a thermistor whose resistance value changes according to the external temperature, and divides the voltage according to the fixed resistance and the resistance value of the thermistor.

The thermistor decreases in resistance when the external temperature rises.

The second voltage divider includes first and second fixed resistors having a fixed resistance value regardless of the external temperature, and divides the voltage according to the resistance values of the first and second fixed resistors.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the present invention;

2 is a circuit diagram of a battery protection circuit according to an embodiment of the present invention.

Referring to FIG. 2, the protection IC 21 may include a power supply terminal VDD, a ground terminal VSS, a discharge blocking signal output terminal DO for outputting an overdischarge and an overcurrent blocking signal, and a charge for outputting an overcharge blocking signal. A blocking signal output stage CO and an overcurrent sensing stage VM are provided. The protection IC 21 has an overcurrent cutoff value suitable for the characteristics of the portable electronic device at design time, and provides a control signal for blocking the discharge of the battery when a current higher than the cutoff value set by the overcurrent detection stage (VM) is detected. Output The first field effect transistor (QFET) Q21 acts as a discharge control switch to block the discharge of the battery by operating according to the over-discharge blocking signal from the discharge blocking signal output terminal DO of the protection IC 21. The second FET Q22 acts as a charge control switch to block charging of the battery by operating according to the overcharge blocking signal from the charge blocking signal output terminal CO of the protection IC 21. In addition, the first to fifth capacitors C21, C22, C23, C24, and C25 serve to prevent external noise and static electricity. In addition, the resistor R22 serves to prevent a reverse current to the protection IC 21 when a reverse power is applied to the protection circuit.

In addition, the temperature detector 23 detects the external temperature and serves to adjust the output value according to the external temperature, and the resistance value is fixed according to the fixed resistors R23, R25 and R26 having a fixed resistance value and the external temperature. And a comparator 22 and a resistor R24 composed of a thermistor. The comparator 22 inputs the divided voltage by the first voltage divider composed of the resistor R23 and the resistor R24 to both input terminals +, and the second voltage composed of the resistor R25 and the resistor R26. The divider voltage by the divider is input to the negative input terminal (-) and the output signal is adjusted and output according to the comparison result thereof. However, the comparator 22 is configured as an open drain type so that the comparator 22 outputs a low level signal when the input voltage to the positive input terminal (+) is greater than the input voltage to the negative input terminal (−). Otherwise, a high level signal is output. Here, the resistors R23, R25, and R26 are fixed resistors, and the resistor R24 is constituted by a thermistor having a property of lowering the resistance value when the external temperature rises to a predetermined temperature, for example, 60 ° C or more, so that the external temperature exceeds the predetermined temperature. When the voltage rises to, the voltage divided by the first voltage divider consisting of the resistor R23 and the resistor R24 is greater than the voltage divided by the second voltage divider composed of the resistor R25 and the resistor R26 so that the comparator 22 Output a low level signal. This is because when the external temperature rises above the set temperature, the resistance value of the resistor R24 becomes negligibly low, and thus the output voltage of the first voltage divider becomes a voltage applied to the resistor R23. On the other hand, the resistor R27 connected to the output terminal of the comparator 22 serves to stabilize the level of the output terminal of the comparator 22 as a pull-up resistor. In addition, the third FET Q23 driven according to the output signal of the comparator 22 is driven according to the level of the output signal according to the temperature detected by the comparator 22 to serve as a temperature control switch controlling the charging of the battery. Do it. The diode D21 serves as a discharge path of the battery, which improves the discharge efficiency in addition to the discharge through the parasitic diode of the third FET Q23.

Referring to the operation of the battery protection circuit according to an embodiment of the present invention configured as described above are as follows.

When handling a mobile communication terminal or a battery pack, if a short or over discharge factor occurs in a terminal of a charger or a portable device, a voltage proportional to the current flowing by the internal resistance of the first FET Q21 and the second FET Q22. Is generated, and this voltage is sensed through the overcurrent sensing stage VM of the protection IC 21.

Subsequently, when the corresponding voltage is equal to or greater than the set overcurrent cutoff value, the protection IC 21 drops the signal of the discharge cutoff signal output terminal DO to a low level to turn off the first FET Q21 to block overdischarge of the battery.

In addition, during overcharging, the battery of the battery is blocked by turning off the second FET Q22 by lowering the signal of the charge blocking signal output terminal CO to a low level.

On the other hand, when the external temperature rises above a set temperature, for example, 60 ° C. or more, the resistance value of the resistor R24 decreases, and accordingly, the resistance value of the resistor R24 becomes small enough to be negligible, such that the resistance R23 and the resistance R24 are reduced. The division voltage by is greater than the division voltage by the resistors R25 and R26. Accordingly, the comparator 22 inputs them to output a low level signal, and the third FET Q23 is turned off according to the output signal of the low level comparator 22 to control the battery.

As described above, according to the present invention, a battery protection circuit is configured to include a temperature detector for detecting an external temperature and adjusting a level of an output signal, and a temperature control switch driven according to an output signal of the temperature detector to control charging of the battery. Even if the external temperature rises, the battery does not explode, thereby extending the life of the battery and preventing deterioration of protection circuits and terminals inside the battery.

Claims (5)

A protection IC for detecting overcharge and overdischarge and generating a blocking signal; A cutoff switch which cuts off a current according to a cutoff signal from the protection IC; A temperature detector for detecting an external temperature and adjusting and outputting an output signal according thereto; And a control switch for controlling the battery according to the output signal of the temperature detector, The temperature detector includes a first voltage divider for distributing a voltage that varies with the external temperature; A second voltage divider for distributing a fixed voltage independent of the external temperature; And And a comparator for inputting the voltages divided by the first and second voltage dividers, comparing them, and outputting the result. delete The display device of claim 1, wherein the first voltage divider comprises: a fixed resistor having a fixed resistance value regardless of the external temperature; And A thermistor whose resistance is changed according to the external temperature; A battery protection circuit for distributing a voltage according to the fixed resistance and a resistance value of the thermistor. 4. The battery protection circuit according to claim 3, wherein the thermistor decreases its resistance value when the external temperature rises. The voltage divider of claim 1, wherein the second voltage divider includes first and second fixed resistors having fixed resistances regardless of the external temperature, and divides the voltages according to resistance values of the first and second fixed resistors. Battery protection circuit.

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