KR0175452B1 - Overdischarging protection circuit - Google Patents

Abstract

1. TECHNICAL FIELD OF THE INVENTION

The present invention relates to an over-discharge cut-off circuit that improves over-discharge according to a recovery characteristic of a battery.

2. The technical problem to be solved by the invention

This is to eliminate over discharge due to the recovery characteristics of the battery.

3. Summary of Solution to Invention

The memory backup power output terminal of the battery is connected to one end of the over-discharge disconnect switch, and the power supply terminal of the memory is connected to the other side of the over-discharge disconnect switch, and over-discharged between the power terminal of the memory and the other side of the over-discharge disconnect switch The over-discharge detection terminal of the previous detection means is connected, and the output terminal of the over-discharge detection signal of the over-discharge detection means is connected to the over-discharge disconnect switch.

4. Important uses of the invention

Cordless phone

Description

Over-discharge cutoff circuit improves over-discharge caused by battery recovery characteristics

1 is a configuration diagram of a conventional over-discharge protection circuit.

2 is a diagram showing recovery characteristics of the battery shown in FIG.

Figure 3 is an over-discharge blocking circuit to improve the over-discharge generated according to the recovery characteristics of the battery according to the present invention.

* Explanation of symbols for main parts of the drawings

10: power adapter 20: first power supply

21: first regulator 22: second power supply

23: second regulator 24: battery

25: over-discharge disconnect switch 26: over-discharge detection unit

27: key input unit 28: control unit

29: digital signal processor 30: memory

The present invention relates to an over-discharge cut-off circuit, and more particularly, to an over-discharge cut-off circuit having improved over-discharge of the battery according to the battery recovery characteristics.

Nickel cadmium (Ni-Cd) is the most widely used battery.

The telephone using the nickel cadmium (Ni-Cd) as a battery is shown in FIG.

Referring to FIG. 1, the power adapter 10 includes a transformer T for inducing an AC power applied to the primary winding to the secondary winding, and an AC power AC induced at the secondary winding. The bridge diode BD rectified by a DC power supply, the capacitor C1 which removes harmonic components contained in the DC power supply, and outputs it to the smooth DC power supply, and the smooth DC power supply are applied to the jack J2 described above. It consists of the jack J1.

The first power supply unit 20 stabilizes the smooth DC power inputted through the jack J2 and outputs the first regulator 21 to the first DC power in a reverse direction. It is composed of a reverse blocking diode (D1) to prevent the supply to the regulator 21, the first DC power supply to the operating power of the key input unit 27, the control unit 28, and the digital signal processing unit 29 do.

The second power supply 22 is a second regulator 23 which stabilizes the smooth DC power input through the jack J2 and outputs the same to the second DC power, and the second DC power is reversed. A reverse blocking diode D2 for preventing supply to the second regulator 23, and a battery 24 for charging the second DC power supply to a memory backup source.

The overdischarge detection unit 26 detects overdischarge according to the voltage state of the memory backup power supply and generates an overdischarge detection signal.

The over-discharge disconnect switch 25 performs a switching operation in response to the over-discharge detection signal, and when the over-discharge disconnect switch is ON and power is not applied from the power adapter 10, the memory backup power supply When the over-discharge disconnect switch 25 is in an OFF state, the memory backup power is not applied to the memory 30. That is, when the power is cut off, the normal current cannot be supplied to the memory 30. Therefore, when the power is cut off, the current is supplied to the memory 30 through the overdischarge cutoff switch 25. The current supplied at this time is about 25mA, which is called the memory backup power supply.

In addition, the memory 30 maintains the memory through the power applied through the second regulator during normal operation, and backs up the memory from the battery 24 when the power is not applied from the power adapter 10. When the power is supplied, the shortcut key of the phone and the data input by the user are stored.

FIG. 2 is a diagram illustrating battery recovery characteristics of the battery illustrated in FIG. 1.

If power is not applied from the power adapter 10 due to a power failure, the voltage gradually decreases to the voltage of the battery 24 as shown in FIG. 2A (2a). Discharges a discharge current of about 25 mA to the memory 30 for memory backup. However, when the memory backup power supply reaches the overdischarge blocking voltage 3.4V shown in FIG. 2A, the overdischarge detecting unit 26 detects this and generates the overdischarge detection signal to generate the overdischarge disconnecting switch. (25). Correspondingly, the over-discharge disconnect switch 25 is switched off at the time axis D at (2a) shown in FIG. 2 to block the memory backup power from being input to the memory 30. In general, the voltage increases when the battery is not powered. Therefore, the voltage of the battery 24 rises to about 3.9V due to the battery recovery characteristic of the battery 24 having a current of about 10 μA from the time point D to the time E in the time axis of (2a) shown in FIG. Then, the overdischarge detection unit 26 detects this and switches on the overdischarge disconnecting switch 25. Accordingly, the battery 24 consumes a memory backup power for data storage of the memory 30. . Therefore, this process is repeated from the time point D to the time point I of FIG. 2A, and the battery is over-discharged according to the hysteresis characteristics as shown in FIG. 2B.

As described above, the over-discharge disconnect switch continues the switching operation due to the battery recovery characteristic, so that the voltage charged in the battery is over-discharged, and thus the battery is not charged even when the battery is recharged again.

Accordingly, an object of the present invention is to provide an over-discharge blocking circuit for blocking over-discharge according to the recovery characteristics of the battery.

The over-discharge cut-off circuit according to the present invention for achieving the above object is connected to the over-discharge cutoff switch 25 to the output terminal of the battery, the output terminal and the memory of the over-discharge cutoff switch 25, the over-discharge cutoff The overdischarge disconnecting switch 26 connects the overdischarge detection unit 26 to an output terminal of the switch 25 and the connection point of the memory 30 and outputs a control line from which the overdischarge detection signal is output from the overdischarge detection unit 26. It is characterized by being configured to connect to.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

3 is a block diagram of an over-discharge blocking circuit to improve the over-discharge generated according to the recovery characteristics of the battery according to the present invention.

In the configuration diagram of the over-discharge cut-off circuit shown in FIG. 1, only the position of the over-discharge detection unit is connected between the over-discharge cutoff switch and the memory.

Accordingly, if power is not applied from the power adapter 10 due to a power failure, the battery 24 supplies a current of 25 mA to the memory 30 to back up the memory. Therefore, the battery gradually supplies current to the memory 30 at time C as shown in FIG. 2A in FIG. Therefore, the voltage of the battery gradually decreases, and if the current is not supplied from the power adapter 10 until the point D shown in FIG. 2A of FIG. 2A, the overdischarge detection unit 26 switches the switch 25. By blocking the power supply from the battery 24 is blocked. Therefore, the switch 25 is blocked so that the overdischarge detection unit 26 does not turn on the switch even when the voltage of the battery rises from the time point D to the time E as shown in FIG. 2A of FIG. 2. Therefore, the battery can be prevented from being over discharged.

As described above, the present invention has the advantage of preserving the battery by blocking the over-discharge according to the recovery characteristics of the battery.

Claims (3)

An over-discharge breaking circuit that improves over-discharge according to a recovery characteristic of a battery for protecting data in a memory in case of a power failure, comprising: a transformer for inducing AC power applied to a primary winding to a secondary winding; A power adapter comprising a bridge diode rectified by a power source, a capacitor for removing harmonic components contained in the DC power source and outputting the smoothed DC power source, and a power terminal for outputting the smooth DC power source to another power source terminal; A regulator for stabilizing the smooth DC power input through the other power supply terminal and outputting the DC power; a reverse blocking diode for preventing the DC power from being reversed and being supplied to the regulator again; A power supply means composed of a battery charged with backup power; The memory receiving the memory backup power and continuing the storage of the data; Over-discharge detection means for detecting over-discharge of the memory backup power supply and outputting an over-discharge detection signal; And an over-discharge disconnecting switch for switching the memory backup power supply from being over-discharged to the memory by switching in response to the over-discharge detection signal. The memory device of claim 1, wherein the memory backup power output terminal of the battery is connected to one end of the over-discharge disconnect switch, a power supply terminal of the memory is connected to the other side of the over-discharge disconnect switch, and a power supply terminal of the memory. The overdischarge detection terminal of the overdischarge detection means is connected between the other sides of the overdischarge disconnection switch, and the output terminal of the overdischarge detection signal of the overdischarge detection means is connected to the overdischarge disconnection switch to detect the overdischarge. And means for generating the over-discharge detection signal to block the over-discharge cutoff switch to block over-discharge of the battery when the level of the memory backup power exceeds the over-discharge cut-off power. The over-discharge blocking circuit according to claim 1 or 2, wherein the battery is a nickel-cadmium battery.