CS240042B1 - Wiring for automatic disconnection of the power supply of the electronic device - Google Patents

Abstract

The present invention concerns a circuit for automatic disconnection of the supply voltage of an electronic device when the set input current value is exceeded and reconnection after the current overload is removed. The voltage at the collector-emitter junction of the fourth transistor T4 is sensed as the control voltage for the function of the entire circuit. The circuit is activated by positive pulses at input terminal 1. After the overload is removed, the supply voltage is reconnected by another positive pulse. By changing the transistors used, the circuit can also be used for connecting a negative supply voltage. The circuit is suitable for powering and controlling various remote electronic devices, especially in telecommunications. The indicator diode 'SD' serves to signal the operation of the circuit?

Description

BACKGROUND OF THE INVENTION The present invention relates to a circuit for automatically disconnecting the supply voltage of an electronic device when the input current is exceeded and to reconnect the supply voltage after the current overload has been removed.

Known circuits utilize a low-value sensing resistor to detect the magnitude of the current flow at which the voltage is sensed. This voltage is a control variable for other circuits that disconnect the Regulation from the power supply in case of overload. The disadvantage is the large voltage drop across the sensing resistor at higher currents, resulting in a large power loss. Known connections do not automatically connect the power supply to the normal state after adjusting the machine's operating mode. They must be operated manually.

The purpose of the invention is to overcome these disadvantages. According to the principle of the invention, this is achieved in that the input terminal is connected via a first resistor based on a first transistor whose emitter is connected via a first capacitor to a positive terminal of the source and whose collector is connected via a second resistor to a positive terminal of the source based on a second transistor and through a fourth resistor based on a fifth transistor. The collector of the fifth transistor is connected through the eighth resistor to the output terminal connected through the fourth diode to the negative terminal of the power supply. The emitter of the fifth transistor is connected on the basis of the sixth transistor, whose emitter is connected to the negative terminal of the source and whose collector is connected on the basis of the second transistor. The collector of the second transistor is connected to the emitter of the first transistor and further through the first and second Zemer's diodes to the negative terminal of the source. The emitter of the second transistor is connected via a seventh resistor based on a fourth transistor and via a fifth resistor

240 042

- 2 and 6th variable resistance on the positive terminal of the power supply. The runner of the sixth variable resistor is connected on the basis of a third transistor whose emitter is connected to the positive terminal of the source and whose collector is connected via a third Zener diode based on the second transistor. The collector of the fourth transistor is connected to the output terminal and its emitter is connected to the positive terminal of the source, which is connected via the second capacitor on the basis of the fifth transistor.

The control value of this circuit is the magnitude of the voltage at the collector-emitter transition of the Fourth Transistor, dependent on the current flowing through. The circuit has no power loss even at higher currents. It automatically disconnects and reconnects the power supply.

An example of the invention is further described by means of a drawing. The input terminal 1 is connected via the first resistor R1 based on the first transistor T1.

Its emitter is connected via the first capacitor C1 to the positive terminal + U of the source, to the collector of the second transistor T2 and through the first and second Zener diodes D1. D2 to the negative terminal -U of the power supply. The collector of the first transistor T1 is connected via the second resistor R2 to the positive terminal + U of the source, through the fourth resistor R4 based on the fifth transistor T5 and through the third resistor R3 based on the second transistor T2. This base is connected to the collector of the sixth transistor T6 and via the third Zener diode D3 to the collector of the third transistor T3. Its

And the emitter is connected to the positive terminal of the + U source. The base of the third transistor T3 is connected to a variable sixth resistor R6. one end of which is connected to the positive terminal + U of the source and the other end is connected to the emitter of the second transistor T2 via the fifth resistor R5.

This emitter is connected to the 7th resistor R7. base of the fourth transistor T4. Its emitter is connected to the positive terminal + U of the source, its collector is connected to the output terminal 2 and through the fifth diode D5, the indication diode SD and the ninth resistor R9 to the negative terminal -U of the source. The output terminal 2 is connected via the fourth diode D4 to the negative terminal -U of the source and through the eighth resistor R8 to the collector of the fifth transistor T5, whose emitter is connected on the basis of the sixth transistor T6. The emitter of the sixth transistor T6 is connected to the positive terminal + U of the source to which the base of the fifth transistor T5 is connected via the second capacitor C2>

The first transistor T1 is opened by positive voltage pulses coming to the input terminal 1. The negative potential from the collector of the first transistor T1 is applied via a third resistor R3 based on the second transistor T2. The second transistor T2 opens and the negative potential

- 3,240,042 of its emitter is applied through a seventh resistor R7 based on a fourth transistor T4. If negative voltage is applied to output terminal 2, current will flow through the fourth transistor T4. A voltage is created at the collector-emitter transition, which is the control voltage for the fifth and sixth transistors T5. T6. If the value of this voltage increases due to the increased flow current, both transistors T5 will open. T6. The positive potential from the collector of the sixth transistor T6 is applied based on the second transistor T2, which is closed.

This interrupts the negative potential at the emitter of the second transistor 23 and based on the fourth transistor T4, which is closed. The operating point of the circuit can be set in the output current range of 0.5 to 5 A by a variable resistor R6 connected in the base of the third transistor T3, by means of which the feedback between the circuits of the second and fourth transistor T2 is realized. T4 and the circuit of the sixth transistor T6. The wiring is brought to a standstill by disconnecting the positive voltage from the input terminal 1. If the current overload of the output at the output terminal 2 persists, then at the next positive pulse on the input terminal 1, the wiring is immediately put into the quiescent state. If the current overload has already been removed, the fourth transistor T4 opens and the wiring is automatically switched to normal operating mode.

The circuit according to the invention can also operate with a constant positive voltage at the input terminal 1, but in the event of an overload, it is necessary to operate an additional circuit which at certain time intervals connects the positive terminal to the input terminal 1. When the overload is removed, the activity resumes automatically. By changing the transistors used, the circuit can also be used to connect a negative supply voltage. The SD diode is used to indicate the wiring activity.

It is recommended to use the wiring to power and control various remote electronic devices. For smaller current consumption, up to 2 A, the wiring can also be implemented in an integrated design.

Claims (1)

FIELD OF THE INVENTION 240 042 Wiring for automatic disconnection of the power supply of the electronic device when the set input current is exceeded »· characterized in that the input terminal (1) is connected via a first resistor (R1) based on a first transistor (TI) whose emitter is connected through a first capacitor (Cl ) to the positive terminal (+ U) of the source and whose collector is connected both through the second resistor (R2) to the positive terminal (+ U) of the source and through the third resistor (R3) based on the second transistor (T2) and through the fourth resistor (R4) ) based on a fifth transistor (T5), the collector of which is connected via an eighth resistor (R8) to an output terminal (2) connected via a fourth diode (D4) to a negative terminal (-U) of the source, and whose emitter is connected transistor (T.6), whose emitter is connected to the negative terminal (-U) of the source and whose collector is connected on the basis of the second transistor (T2), whose collector is connected to the emitter of the first transistor (T1) and with a second Zener diode (D1, D2) to the negative terminal (-U) of the source, and whose emitter is connected both through a seventh resistor (R7) based on a fourth transistor (T4) and a fifth resistor (R5) and a sixth variable resistor (R6) to the positive terminal (+ U) of the source, wherein the runner of the sixth variable resistor (R6) is connected on the basis of a third transistor (T3) whose emitter is connected to the positive terminal (+ U) of the source and whose collector is connected through the third Zener a diode based on a second transistor (T2), while a collector of a fourth transistor (T4) is connected to an output terminal (2) and its emitter is connected to a positive terminal (+ U) of a source which is connected via a second capacitor (Cl) transistor (T5).