KR790001953Y1 - Protecting device of over discharge in emergency exit lamp for battery - Google Patents

Abstract

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Description

Battery over-discharge prevention device such as emergency exit induction lamp

1 is a circuit diagram of the present invention.

2 is an explanatory diagram of reference voltage characteristics of the present invention.

The present invention relates to a circuit of the over-discharge prevention device to prevent over-discharge used as an emergency power source in the event of a power failure in the configuration of the emergency exit induction lamp. Since the overdischarge of the battery causes many closures, the circuit of the overdischarge prevention device to prevent the overdischarge has already been developed and used. However, since the overdischarge prevention device circuit is mostly the method of using the zener diode as a reference voltage, the emergency exit induction lamp In the prevention of overdischarge of low voltage (3V or less), the zener diode of low voltage (2.25V or less) is not produced, and the circuit of the low-voltage overdischarge prevention device has a drawback that cannot be put into practical use as a simple circuit diagram. I'm doing it.

The present invention solves the above-mentioned shortcomings. By using the threshold voltage by the diode's structural characteristics, it is connected in series to increase the threshold voltage to obtain the necessary reference voltage and operate the transistor circuit using this voltage. Load control method, even if the battery power is under 3V

The emergency lamp 10 is turned off when the commercial power is applied to the input terminals (A) and (C). In the state where the battery 11 is being charged, since the charging voltage is applied to the base of the PNP type load control transistor 5, it is reverse biased so that the emergency lamp 10 is turned off, but the commercial power is removed. The reverse bias caused by the charging voltage is removed so that the + voltage by the battery 11 for emergency power is cut off from the diode 1 and the load control transistor 5 is in a state that can be controlled by the drive transistor 6. .

Since the voltage of the battery 11 for emergency power is forward biased to the drive transistor 6 through the diodes 2, 3 and 4 and the bias adjustment resistor 8, the transistor 6 is operated so that the load control transistor is operated. A current is made to flow through the collector which becomes the base current of (5).

Therefore, the load control transistor 5 flows a sufficient forward bias current to switch the emergency lamp 10 by switching operation, and when the voltage of the emergency power battery 11 drops due to prolonged discharge, the diode (2) (3). Each threshold voltage of (4) falls below the sum of the reference voltages. At this time, the bias current of the drive transistor 6 flowing through the diodes (2), (3) and (4) is rapidly reduced to perform the output operation. It becomes impossible.

That is, as shown in FIG. 2, when the voltage of the battery 11 for emergency power drops below the reference voltage of the diodes 2, 3, 4, it flows through the diodes 2, 3, 4; The current becomes almost zero, so that the static resistance of the diodes (2) (3) (4) Is a high resistance in units of hundreds of KΩ and MΩ.

Therefore, since the voltage applied to the base of the drive transistor 6 is divided by the series resistance voltage by the static resistor Rd and the resistor 9, the voltage is lower than the cut-in voltage, so that the base current of the load control transistor 5 is reduced. The emergency lamp 10 is turned off so that the over discharge prevention operation is prevented from being continuously discharged below a predetermined voltage set by the diodes 2, 3, and 4.

Claims (1)

As shown in the figure, in forming an over-discharge prevention circuit of a low voltage battery, a reference voltage in which diodes (2) (3) (4) are connected in series using a known diode there voltage is formed and a reference voltage is used. And over-discharge prevention device for low-voltage emergency exit induction by controlling the load output by controlling the circuit of the resistor (9), the transistor (6), and the transistor (5).