KR20050112621A - Battery protection circuit - Google Patents

Abstract

The present invention relates to a battery protection circuit, wherein the overcharge voltage, overdischarge voltage, overdischarge current, overcharge current, and the like of the battery can be reduced so that current consumption can be reduced by not operating the time delay unit when the charge switch or the discharge switch is turned off. A detection unit for detecting a short state of a load, a time delay enable unit for receiving an output signal of the detector unit and outputting a predetermined signal, a time delay unit for receiving an output signal of the time delay enable unit and outputting a predetermined signal, and a detection unit And a control unit for receiving a signal of the time delay unit and outputting a predetermined control signal, a charging switch for blocking the overcharge voltage or the overcharge current by the output signal of the controller, and the overdischarge voltage, the overdischarge current, or the short by the output signal of the controller. Characterized in that the discharge switch to block the state.

Description

Battery protection circuit

The present invention relates to a battery protection circuit, and more particularly, to a battery protection circuit that can reduce current consumption by not operating the time delay unit when the charge switch or the discharge switch is turned off.

In general, a secondary battery (hereinafter, abbreviated as battery) has a very high energy density, and a protection circuit is built in to protect a user from overcharge or overdischarge. Referring to FIG. 1, a conventional battery protection circuit is illustrated, which is connected in parallel with a battery to detect an overcharge / discharge voltage, a current, and a short during a charge / discharge operation.

That is, the conventional charge / discharge protection circuit is connected between the battery CELL 'and the charger (or the load) (not shown) in parallel to the overcharge voltage detection unit 11' for detecting the overcharge voltage, and the overdischarge voltage. An overdischarge voltage detector 12 'for detecting, an overdischarge current detector 13' for detecting an overdischarge current, an overcharge current detector 14 'for detecting an overcharge current, and a short detector for detecting a short state of a load or a charger. A signal from the overcharge voltage detector 11 ', the overdischarge voltage detector 12', the overdischarge current detector 13 ', the overcharge current detector 14', and the short detector 15 '. A circuit is opened by outputting a constant control signal using signals from the time delay unit 30 ', the various detection units 11' to 15 'and the time delay unit 20' which are output by delaying a predetermined time. By the control signals of the first and second controllers 31 'and 32' and the first controller 31 ' A charge switch 41 'for opening the circuit at the charge voltage or current, and a discharge switch 42' for opening the circuit at the over-discharge voltage, current or short by the control signal of the second controller 32 '. have.

The conventional battery protection circuit protects the battery CELL 'by the following operation.

First, the battery CELL 'protection operation during charging will be described in a state in which terminals Vout +' and terminals Vout- 'of the battery CELL' are connected to a charger (not shown).

The overcharge voltage detector 11 ′ or the overcharge current detector 14 ′ detects an overvoltage or overcurrent of the battery CELL ′ and outputs the same to the time delay unit 20 ′ and the first controller 31 ′. For example, while the output of the overcharge voltage detector 11 'goes from high to low, the time delay unit 20' is operated. When the output of the time delay unit 20 'goes from high to low after a certain time, the first control unit 31' causes the two signals (the signals of the overcharge voltage detector 11 'and the time delay unit 30') to be reduced. After receiving, by outputting a low signal to the charge switch 41 ', the charge switch 41' is turned off. Then, the current flowing through the charger, the terminal Vout + ', the battery CELL', the discharge switch 42 ', the charging switch 41', and the terminal Vout- 'is cut off, and the charging operation is stopped. Here, the operation of the overcharge current detector 14 'is also the same as above.

At this time, the time delay unit 20 'continues to operate while the overcharge state is maintained (the overcharge voltage detector 11' is low), and continuously consumes current.

Next, the battery CELL 'protection operation during discharge will be described with the battery CELL' connected to the load.

The overdischarge voltage detector 12 ', the overdischarge current detector 13', or the short detector 15 'detects an overvoltage, an overcurrent, or a short of the battery CELL', which is then delayed by the time delay unit 20 '. And output to the second control unit 32 '. For example, while the output of the over-discharge voltage detector 12 'goes from high to low, the time delay unit 20' is operated. When the output of the time delay unit 20 'goes from high to low after a predetermined time, the two signals (the signals of the over-discharge voltage detector 12' and the time delay unit 30 ') in the second control unit 32'. After accepting the signal, a low signal is output to the discharge switch 42 'so that the discharge switch 42' is turned off. Then, the current flowing to the load, the terminal Vout- ', the charge switch 41', the discharge switch 42 ', the battery CELL' and the terminal Vout + 'is cut off and the discharge operation is stopped. Here, the operation of the over-discharge current detector 13 'and the short detector 15' is also the same as above.

Of course, the time delay unit 20 'continues to operate while the over-discharge state is maintained (the over-discharge voltage detector 12' is low), and continuously consumes current.

As described above, the conventional battery protection circuit has a structure in which the time delay unit continuously consumes the current of the battery even though the charge switch or the discharge switch is turned off at the time of overcharge voltage, current, overdischarge voltage, current or short. Therefore, the battery protection circuit of the related art not only reduces the capacity of the battery, but also sometimes causes the battery current to continue to be discharged even when over-discharged.

SUMMARY OF THE INVENTION The present invention is to overcome the above-mentioned conventional problems, and an object of the present invention is to provide a battery protection circuit which can reduce the current consumption by not operating the time delay unit when the charge switch or the discharge switch is turned off.

In order to achieve the above object, a battery protection circuit according to the present invention includes a detector for detecting an overcharge voltage, an overdischarge voltage, an overdischarge current, an overcharge current, and a short state of a battery, and a predetermined signal by receiving an output signal of the detector. A time delay enable unit for outputting, a time delay unit for receiving an output signal of the time delay enable unit and outputting a predetermined signal, a controller for receiving signals of the detection unit and the time delay unit and outputting a predetermined control signal; And a discharge switch to block the overcharge voltage or the overcharge current by the output signal of the controller, and a discharge switch to block the overdischarge voltage, the overdischarge current, or the short state by the output signal of the controller.

The time delay unit includes a latch function or the like so that the output of the time delay unit does not change even when the state is disabled.

The detector includes an overcharge voltage detector for detecting an overcharge voltage of the battery, an overdischarge voltage detector for detecting an overdischarge voltage of the battery, an overdischarge current detector for detecting an overdischarge current of the battery, and an overcharge current of the battery. An overcharge current detection unit for detecting a and a short detection unit for detecting a short state of the load.

The control unit may include an overcharge voltage controller configured to receive signals from the overcharge voltage detector and a time delay unit, and output a predetermined control signal to a charge switch and a time delay enable unit, a charge switch to receive signals from the overcharge current detector and a time delay unit; An overcharge current controller for outputting a predetermined control signal to a time delay enable unit, an overdischarge voltage controller for receiving signals from the overdischarge voltage detector and a time delay unit, and outputting a predetermined control signal to a discharge switch and a time delay enable unit; And an over-discharge current control unit for receiving a signal from the over-discharge current detector and a time delay unit and outputting a predetermined control signal to a discharge switch and a time delay enable unit, and a discharge switch and time for receiving a signal from the short detector and the time delay unit. Short for outputting a predetermined control signal to the delay enable part It may be made of a control unit.

Here, when the battery is in an overcharge voltage state, the battery protection circuit outputs a low signal to the overcharge voltage controller and the time delay enable unit, and the time delay enable unit is enabled to provide the time delay unit. Outputs a low signal, and the time delay unit outputs a low signal to the overcharge voltage controller after a predetermined time, and the overcharge voltage controller outputs a low signal to a charge switch by a low signal of the overcharge voltage detector and the time delay unit to turn off At the same time, a low signal is also output to the time delay enable unit so that the time delay enable unit is disabled to become high.

Further, when the battery is in an overcharge current state, the overcharge current detector outputs a low signal to the overcharge current controller and the time delay enable unit, and the time delay enable unit is enabled to output a low signal to the time delay unit. The time delay unit outputs a low signal to the overcharge current controller after a predetermined time, and the overcharge current controller outputs a low signal to a charge switch by a low signal of the overcharge current detector and the time delay unit, and simultaneously turns off the time. A low signal is also output to the delay enable unit so that the time delay enable unit is disabled and brought to a high state.

In addition, when the battery is in an over-discharge voltage state, the over-discharge voltage detector outputs a low signal to the over-discharge voltage controller and the time delay enable unit, and the time delay enable unit is enabled to provide a low signal to the time delay unit. The time delay unit outputs a low signal to the overdischarge voltage controller after a predetermined time, and the overdischarge voltage control unit outputs a low signal to a discharge switch by a low signal of the overdischarge voltage detector and the time delay unit. At the same time, a low signal is also output to the time delay enable unit so that the time delay enable unit is disabled to become a high state.

In addition, when the battery is in an over-discharge current state, the over-discharge current detector outputs a low signal to the over-discharge current control unit and the time delay enable unit, and the time delay enable unit is enabled to provide a low signal to the time delay unit. And the time delay unit outputs a low signal to the over-discharge current controller after a predetermined time, and the over-discharge current controller outputs a low signal to a discharge switch by a low signal of the over-discharge current detector and the time delay unit. At the same time, a low signal is also output to the time delay enable unit so that the time delay enable unit is disabled to become a high state.

In addition, when the load is in a short state, the short detector outputs a low signal to the short control unit and the time delay enable unit, the time delay enable unit is enabled to output the low signal to the time delay unit, and the time The delay unit outputs a low signal to the short control unit after a predetermined time, and the short control unit outputs a low signal to a discharge switch by a low signal of the short detection unit and the time delay unit, and turns off the low signal. The delay control unit also outputs a low signal to the time delay enable unit. A signal is output so that the time delay enable portion is disabled to a high state.

As described above, the battery protection circuit according to the present invention turns off the charge switch or the discharge switch at the time of the overcharge voltage, the overdischarge voltage, the overdischarge current, the overcharge current or the short circuit by the time delay enable part and at the same time the operation of the time delay part. It is also possible to stop the current consumption by the time delay unit.

Therefore, the battery protection circuit according to the present invention not only increases the battery capacity or the usable time, but also suppresses the complete discharge state and extends the life of the battery.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings such that those skilled in the art may easily implement the present invention.

2, a battery protection circuit according to the present invention is shown.

As shown, the battery protection circuit according to the present invention includes a detector 10 for detecting various states of the battery CELL, a time delay enable unit 20 for outputting a disable or enable signal, and a predetermined time delay. It is operated by the output signal of the control unit 40 and the control unit 40 for receiving a signal of the time delay unit 30, the detector 10 and the time delay unit 30 to output a signal and output a predetermined control signal It consists of a charge switch 51 and a discharge switch (52).

The charge switch 51 and the discharge switch 52 may be N-channel field effect transistors in which parasitic diodes are formed. In addition, each of the switches 51 and 52 may be driven by a charge switch driver 61 and a discharge switch driver 62 connected to the gate.

First, the detector 10 may include an overcharge voltage detector 11, an overdischarge voltage detector 12, an overdischarge current detector 13, an overcharge current detector 14, and a short detector 15. An output terminal 10 is connected to the time delay enable unit 20 and the control unit 40.

The overcharge voltage detector 11 is connected in parallel to the battery CELL so that a high signal is output when the battery CELL is in a normal state, and a low signal when the battery CELL is in a normal state. )

The over-discharge voltage detector 12 is connected in parallel to the battery CELL so that the high signal when the battery CELL is in a normal state and a low signal when the over-discharge voltage state is in the time delay enable unit 20 and the controller. Output to 40.

The over-discharge current detector 13 is connected in parallel with both ends of the charge switch 51 and the discharge switch 52 (that is, the terminal VM and the terminal VSS) so that a high signal is generated when the battery CELL is in a normal state. In the full current state, the low signal is output to the time delay enable unit 20 and the control unit 40.

The overcharge current detector 14 is connected in parallel with both ends of the charge switch 51 and the discharge switch 52 (that is, the terminal VM and the terminal VSS) so that a high signal is generated when the battery CELL is in a normal state. In the state, the low signal is output to the time delay enable unit 20 and the control unit 40.

In addition, the short detector 15 is connected in parallel with both ends of the charge switch 51 and the discharge switch 52 (that is, the terminal VM and the terminal VSS) so that a high signal is generated when the load is in a normal state, and in a short state. The low signal is output to the time delay enable unit 20 and the control unit 40.

All such detection unit 10 can be implemented using a conventional op amp or its equivalent, but is not limited to a specific device.

The time delay enable unit 20 is connected to an output terminal of the overcharge voltage detector 11, the overdischarge voltage detector 12, the overdischarge current detector 13, the overcharge current detector 14, or the short detector 15. The input terminal is connected. In addition, the time delay enable unit 20 has an output terminal connected to the time delay unit 30. The time delay enable unit 20 outputs a low signal to the time delay unit 30 when the output from the detection unit 10 goes from the high state to the low state so that the time delay unit 30 is enabled. .

The time delay unit 30 is connected to an output terminal of the time delay enable unit 20. In addition, the time delay unit 30 has an output terminal connected to the control unit 40. As such, when the low signal is output from the detector 10, the time delay unit 30 outputs the low signal to the controller 40 after a predetermined time has elapsed. In this case, the time delay unit 30 includes a latch function or the like so that the output does not change even when it is in a disabled state.

The controller 40 includes an overcharge voltage controller 41, an overcharge current controller 42, an overdischarge voltage controller 43, an overdischarge current controller 44, and a short controller 45.

The overcharge voltage controller 41 has an input terminal connected to the output terminals of the overcharge voltage detector 11 and the time delay unit 30. In addition, the overcharge voltage controller 41 has an output terminal connected to the charge switch 51 and the time delay enable unit 20. Therefore, when the battery CELL is in the overcharge voltage state, a low signal is input from the overcharge voltage detector 11 and the time delay unit 30, respectively, and then the low signal is supplied to the charge switch 51 and the time delay enable unit 20. Output the signal.

The overcharge current controller 42 has an input terminal connected to an output terminal of the overcharge current detector 14 and the time delay unit 30. In addition, the overcharge current controller 42 has an output terminal connected to the charge switch 51 and the time delay enable unit 20. Accordingly, when the battery CELL is in an overcharge current state, a low signal is input from the overcharge current detector 14 and the time delay unit 30, respectively, and then the low signal is supplied to the charge switch 51 and the time delay enable unit 20. Output the signal.

The overdischarge voltage controller 43 has an input terminal connected to the output terminals of the overdischarge voltage detector 12 and the time delay unit 30. In addition, the overdischarge voltage controller 43 has an output terminal connected to the discharge switch 52 and the time delay enable unit 20. Therefore, when the battery CELL is in the over-discharge voltage state, the low signal is input from the over-discharge voltage detector 12 and the time delay unit 30, respectively, and then the discharge switch 52 and the time delay enable unit 20 are received. Outputs a low signal.

The overdischarge current controller 44 has an input terminal connected to the output terminals of the overdischarge current detector 13 and the time delay unit 30. In addition, the overdischarge current control unit 44 has an output terminal connected to the discharge switch 52 and the time delay enable unit 20. Accordingly, when the battery CELL is in the over-discharge current state, the low signal is input from the over-discharge current detector 13 and the time delay unit 30, respectively, and then the discharge switch 52 and the time delay enable unit 20 are received. Outputs a low signal.

The short controller 45 has an input terminal connected to an output terminal of the short detector 15 and the time delay unit 30. In addition, the short control unit 45 has an output terminal connected to the discharge switch 52 and the time delay enable unit 20. Therefore, when the load is in the short state, the low signal is input from the short detector 15 and the time delay unit 30, respectively, and then the low signal is output to the discharge switch 52 and the time delay enable unit 20.

The charge switch 51 is connected to the overcharge voltage controller 41 and the overcharge current controller 42 through a charge switch driver 61. Therefore, when either the low charge signal is output from the overcharge voltage controller 41 or the overcharge current controller 42, the signal is turned off, and the charging operation of the battery CELL is stopped.

The discharge switch 52 is connected to the over-discharge voltage control unit 43, the over-discharge current control unit 44, and the short control unit 45 through a discharge switch driver 62. Therefore, when any one of the low discharge voltages from the over-discharge voltage control unit 43, the over-discharge current control unit 44, or the short control unit 45 outputs a low signal, the discharge operation of the battery CELL is stopped.

Referring to FIG. 3A, a block diagram of a time delay enable unit in a battery protection circuit according to the present invention is shown. Referring to FIGS. 3B and 3C, a logic table of a time delay enable unit is shown. 4A to 4E, there is shown a timing chart for explaining the operation of the battery protection circuit according to the present invention. The operation of the battery protection circuit according to the present invention will be described with reference to these figures and FIG. 2 already described above.

Here, for convenience of description, in Fig. 2, Figs. 3A to 3C, and Figs. 4A to 4E, reference numeral E denotes an output terminal of the overcharge voltage detector 11, I denotes an output terminal of the overdischarge voltage detector 12, and F denotes that Output terminal of the over-discharge current detector 13, J is the output terminal of the overcharge current detector 14, N is the output terminal of the short detector 15, D is the output terminal of the time delay enable section 20, M is Output terminal of the time delay unit 30, H is the output terminal of the overcharge voltage control unit 41, L is the output terminal of the overcharge current control unit 42, K is the output terminal of the over-discharge voltage control unit 43, G is over-discharge The output terminal C of the all current control part 44 is an output terminal of the short control part 45. In addition, the logical table shown in Figs. 3b and 3c above is shown as a logical formula as follows.

[Battery Overcharge Voltage State]

First, since the voltage of the battery CELL is smaller than the reference voltage VREF1 of the overcharge voltage detector 11 in the normal state, the E of the overcharge voltage detector 11 is high. Accordingly, D of the time delay enable unit 20 is also high, M of the time delay unit 30 is also high, and H of the overcharge voltage control unit 41 is also high. Of course, in this state, the charge switch 51 is in an on state.

On the other hand, when the battery CELL is in the overcharge voltage state, the voltage of the battery CELL increases as compared with the reference voltage VREF1 of the overcharge voltage detector 11, so that the E of the overcharge voltage detector 11 is in a low state. As a result, the D of the time delay enable unit 20 is also low, and the M of the time delay unit 30 is also low (time delay unit 30 is enabled). As a result, the H of the overcharge voltage control unit 41 is also low, whereby the charge switch 51 is turned off to stop the charging operation of the battery CELL. At this time, the overcharge voltage control unit 41 outputs a low signal to the time delay enable unit 20 so that the D of the time delay enable unit 20 is in a high state so that the time delay unit 30 is disabled. Able state is entered. Of course, the time delay unit 30 is in a disabled state and remains low by the latch function without current consumption. (See the timing chart of FIG. 4A.) That is, the time delay after the charge switch 51 is turned off. Current consumption by the unit 30 is eliminated.

[Battery Overcharge Current State]

First, in the normal state, since the total voltage of the charge switch 51 and the discharge switch 52 (that is, the voltage detected by the terminal VM and the terminal VSS) is smaller than the reference voltage VREF3 of the overcharge current detector 14, the overcharge current J of the detector 14 is in a high state. Accordingly, D of the time delay enable unit 20 is also high, M of the time delay unit 30 is high, and L of the overcharge current control unit 42 is also high. Of course, in this state, the charge switch 51 is in an on state.

On the other hand, when the battery CELL is in the overcharge current state, the total voltage of the charge switch 51 and the discharge switch 52 (that is, detected by the terminal VM and the terminal VSS) is compared with the reference voltage VREF3 of the overcharge current detector 14. Since the voltage) becomes large, the J of the overcharge current detection unit 14 goes low. As a result, the D of the time delay enable unit 20 is also low, and the M of the time delay unit 30 is also low (time delay unit 30 is enabled). As a result, the L of the overcharge current controller 42 is also low, and thus the charge switch 51 is turned off to stop the charging operation of the battery CELL. At this time, the overcharge current control unit 42 outputs a low signal to the time delay enable unit 20 so that the D of the time delay enable unit 20 is in a high state so that the time delay unit 30 is disabled. Able state is entered. Of course, the time delay unit 30 is in a disabled state and remains low by the latch function without current consumption. (See the timing chart of FIG. 4B.) That is, the time delay after the charge switch 51 is turned off. Current consumption by the unit 30 is eliminated.

[Battery Over Discharge Voltage Status]

First, since the voltage of the battery CELL is larger than the reference voltage VREF1 of the overdischarge voltage detector 12 in the normal state, the I of the overdischarge voltage detector 12 is high. Accordingly, D of the time delay enable unit 20 is also high, M of the time delay unit 30 is also high, and K of the overdischarge voltage control unit 43 is also high. Of course, the discharge switch 52 is on.

On the other hand, when the battery CELL is in the over-discharge voltage state, the voltage of the battery CELL becomes smaller than the reference voltage VREF1 of the over-discharge voltage detector 12, so that the state of I in the over-discharge voltage detector 12 is low. do. As a result, the D of the time delay enable unit 20 is also low, and the M of the time delay unit 30 is also low (time delay unit 30 is enabled). As a result, K of the over-discharge voltage control unit 43 also becomes low, whereby the discharge switch 52 is turned off to stop the discharge operation of the battery CELL. At this time, the over-discharge voltage control unit 43 outputs a low signal to the time delay enable unit 20, so that the D of the time delay enable unit 20 becomes high and the time delay unit 30 The disabled state. Of course, the time delay unit 30 is in a disabled state and remains low by the latch function without current consumption. (See the timing chart of FIG. 4C.) That is, the time delay after the discharge switch 52 is turned off. Current consumption by the unit 30 is eliminated.

[Battery Over Discharge Current State]

First, in the normal state, the total discharge voltage (voltage detected by the terminal VM and the terminal VSS) of the charge switch 51 and the discharge switch 52 is larger than the reference voltage VREF2 of the overdischarge current detection unit 13, so that the overdischarge current F of the detection part 13 is high. Accordingly, D of the time delay enable unit 20 is also high, M of the time delay unit 30 is high, and G of the overdischarge current control unit 44 is also high. Of course, the discharge switch 52 is on.

On the other hand, when the battery CELL is in the over-discharge current state, the total voltage of the charge switch 51 and the discharge switch 52 (as detected by the terminal VM and the terminal VSS) is compared with the reference voltage VREF2 of the over-discharge current detection unit 13. Since the voltage) becomes small, the F of the overdischarge current detection unit 13 goes low. As a result, the D of the time delay enable unit 20 is also low, and the M of the time delay unit 30 is also low (time delay unit 30 is enabled). As a result, the G of the over-discharge current control unit 44 also becomes low, whereby the discharge switch 52 is turned off to stop the discharge operation of the battery CELL. At this time, the over-discharge current control unit 44 outputs a low signal to the time delay enable unit 20, so that the D of the time delay enable unit 20 is in a high state so that the time delay unit 30 The disabled state. Of course, the time delay unit 30 is in a disabled state and remains low due to the latch function without current consumption. (See the timing chart of FIG. 4D.) That is, the time delay after the discharge switch 52 is turned off. Current consumption by the unit 30 is eliminated.

[Load Short State]

First, in the normal state, since the total voltage (voltage detected by the terminal VM and the terminal VSS) of the charge switch 51 and the discharge switch 52 is smaller than the reference voltage VREF4 of the short detector 15, the short detector 15 N is high. Accordingly, D of the time delay enable unit 20 is also high, M of the time delay unit 30 is also high, and C of the short control unit 45 is also high. Of course, the discharge switch 52 is on.

On the other hand, when the battery CELL is in a short state, the total voltage (voltage detected by the terminal VM and the terminal VSS) of the charge switch 51 and the discharge switch 52 becomes larger than the reference voltage VREF4 of the short detector 15. Therefore, N of the short detection unit 15 is in a low state. As a result, the D of the time delay enable unit 20 is also low, and the M of the time delay unit 30 is also low (time delay unit 30 is enabled). As a result, C of the short control section 45 also goes low, whereby the discharge switch 52 is turned off to stop the short state of the load. That is, the discharge operation is stopped. At this time, the short control unit 45 outputs a low signal to the time delay enable unit 20, so that the D of the time delay enable unit 20 is in a high state so that the time delay unit 30 is disabled. It becomes a state. Of course, the time delay unit 30 is in a disabled state and remains low by the latch function without current consumption. (See the timing chart of FIG. 4E.) That is, the time delay after the discharge switch 52 is turned off. Current consumption by the unit 30 is eliminated.

As described above, the battery protection circuit according to the present invention turns off the charge switch or the discharge switch when the overcharge voltage, the overdischarge voltage, the overdischarge current, the overcharge current or the load are shorted by the time delay enable part. At the same time, the operation of the time delay unit is also stopped, whereby the current consumption by the time delay unit can be prevented.

In addition, the battery protection circuit according to the present invention not only increases the battery capacity or the usable time, but also has the effect of extending the life of the battery by suppressing a complete discharge state.

What has been described above is only one embodiment for implementing a battery protection circuit according to the present invention, and the present invention is not limited to the above-described embodiment, and as claimed in the following claims, the gist of the present invention Without departing from the scope of the present invention, any person having ordinary skill in the art will have the technical spirit of the present invention to the extent that various modifications can be made.

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

2 is a circuit diagram illustrating a battery protection circuit according to the present invention.

3A is a block diagram illustrating a time delay enable unit in the battery protection circuit according to the present invention, and FIGS. 3B and 3C are logic tables of the time delay enable unit.

4A to 4E are timing charts for explaining the operation of the battery protection circuit according to the present invention.

<Description of Symbols for Main Parts of Drawings>

CELL; A battery 10; Detector

11; An overcharge voltage detector 12; Over discharge voltage detector

13; An overdischarge current detector 14; Overcharge Current Detector

15; A short detector 20; Time delay enable part

30; Time delay 40; Control

41; An overcharge voltage controller 42; Overcharge Current Control

43; An over discharge voltage controller 44; Over discharge current controller

45; A short control section 51; Charge switch

52; Discharge switch 61; Charge switch driver

62; Discharge switch driver

Claims (9)

A detector for detecting an overcharge voltage, an overdischarge voltage, an overdischarge current, an overcharge current, and a short state of a load of the battery; A time delay enable unit configured to receive an output signal of the detector and output a predetermined signal; A time delay unit configured to receive an output signal of the time delay enable unit and output a predetermined signal; A controller which receives signals from the detector and the time delay unit, and outputs a predetermined control signal; A charge switch to block an overcharge voltage or an overcharge current by an output signal of the controller; And, And a discharge switch for blocking an overdischarge voltage, an overdischarge current, or a short state by an output signal of the controller. The battery protection circuit according to claim 1, wherein the output of the time delay unit does not change even when the time delay unit includes a latch function or the like and becomes disabled. The method of claim 1, wherein the detection unit An overcharge voltage detector configured to detect an overcharge voltage of the battery; An overdischarge voltage detector detecting an overdischarge voltage of the battery; An overdischarge current detector for detecting an overdischarge current of the battery; An overcharge current detector for detecting an overcharge current of the battery; And, And a short detection unit for detecting a short state of the load. The method of claim 3, wherein the control unit An overcharge voltage controller configured to receive signals from the overcharge voltage detector and the time delay unit, and output a predetermined control signal to a charge switch and a time delay enable unit; An overcharge current controller configured to receive signals from the overcharge current detector and the time delay unit, and output a predetermined control signal to a charge switch and a time delay enable unit; An overdischarge voltage controller configured to receive signals from the overdischarge voltage detector and the time delay unit, and output a predetermined control signal to a discharge switch and a time delay enable unit; An overdischarge current controller configured to receive signals from the overdischarge current detector and the time delay unit, and output a predetermined control signal to a discharge switch and a time delay enable unit; And a short controller configured to receive signals from the short detector and the time delay unit, and output a predetermined control signal to a discharge switch and a time delay enable unit. The method of claim 4, wherein If the battery is in an overcharged state, The overcharge voltage detection unit outputs a low signal to the overcharge voltage control unit and the time delay enable unit, The time delay enable unit is enabled to output a low signal to the time delay unit, The time delay unit outputs a low signal to the overcharge voltage controller after a predetermined time, The overcharge voltage control unit outputs a low signal to the charge switch by the low signals of the overcharge voltage detector and the time delay unit, and at the same time, outputs a low signal to the time delay enable unit to disable the time delay enable unit. Battery protection circuit, characterized in that the high state. The method of claim 4, wherein If the battery is in an overcharge current, The overcharge current detection unit outputs a low signal to the overcharge current control unit and the time delay enable unit, The time delay enable unit is enabled to output a low signal to the time delay unit, The time delay unit outputs a low signal to the overcharge current controller after a predetermined time, The overcharge current controller outputs a low signal to the charge switch by the low signals of the overcharge current detector and the time delay unit, and at the same time, outputs a low signal to the time delay enable unit to disable the time delay enable unit. Battery protection circuit, characterized in that the high state. The method of claim 4, wherein If the battery is in an over discharge voltage, The overdischarge voltage detector outputs a low signal to the overdischarge voltage controller and the time delay enable unit. The time delay enable unit is enabled to output a low signal to the time delay unit, The time delay unit outputs a low signal to the over-discharge voltage control unit after a predetermined time, The over-discharge voltage controller outputs a low signal to the discharge switch by the low signals of the over-discharge voltage detector and the time delay unit, and at the same time, outputs a low signal to the time delay enable unit so that the time delay enable unit Battery protection circuitry, disabled and brought to a high state. The method of claim 4, wherein If the battery is in an over-discharge current, The over-discharge current detection unit outputs a low signal to the over-discharge current control unit and the time delay enable unit, The time delay enable unit is enabled to output a low signal to the time delay unit, The time delay unit outputs a low signal to the over-discharge current controller after a predetermined time, The over-discharge current controller outputs a low signal to the discharge switch by the low signals of the over-discharge current detection unit and the time delay unit, and at the same time, outputs a low signal to the time delay enable unit so that the time delay enable unit Battery protection circuitry, disabled and brought to a high state. The method of claim 4, wherein If the load is short, The short detection unit outputs a low signal to a short control unit and a time delay enable unit, The time delay enable unit is enabled to output a low signal to the time delay unit, The time delay unit outputs a low signal to the short control unit after a predetermined time, The short control unit outputs a low signal to a discharge switch by a low signal of the short detection unit and the time delay unit, turns off the output signal, and outputs a low signal to the time delay enable unit to disable the time delay enable unit. Battery protection circuitry, characterized in that the state.