SU1711284A2 - Overload protection arrangement - Google Patents

Abstract

The invention relates to electrical engineering; The aim of the invention is to increase operational reliability by maintaining operability when exposed to short circuits. In case of a short circuit, the load 2 simultaneously closes the regulating first transistor 4 and the compensating third transistor 11 and this is protected from the short circuit current. When the short circuit is eliminated, the circuit returns to its original state. 1 il.

Description

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The invention relates to electrical engineering, can be used in power supply systems of radio engineering devices and is an improvement of the known device according to the author. No. 1339742.

A device for protection against overvoltage of the load is used, which is used in a device for powering electronic equipment, made in the form of a regulating first transistor, controlling the second transistor, the first resistor and the threshold of the first chain consisting of series-connected resistors and zener diodes, - the lecturer-emitter junctions of the first and second transistors are interconnected and are intended to be connected to the first load terminal, and the base of the first trans Stora connected to a first terminal of the first resistor, the second terminal of which is connected to the first output terminal of the first chain is designed for connection to a second terminal of the load and the power source. The device has a compensating third transistor and a threshold second circuit consisting of series-connected resistors and zener diodes. The second terminal output of the first chain is connected to the first output of the collector-emitter junction of the second transistor, and its middle output is connected to the base of the second transistor, the second output of the collector-emitter junction of which is connected to the base of the first transistor. The collector of the third transistor and the first terminal terminal of the second chain are connected to the first, the collector-emitter junction terminal, and the emitter of the third transistor is connected to the second collector-emitter junction terminal of the first transistor, the middle terminal of the second chain is connected to the base of the third transistor. the output through the common wire is connected to the second output of the first resistor. Regulating the first transistor is made of a composite of two transistors.

In order to provide protection against overvoltages of the load in the device, the current arising in the first chain when the voltage of the power source increases (voltage surge) to a certain value acceptable for the load, at which the zener diode is punched, creates a voltage drop at its extreme resistor. opening up to deep saturation of the second transistor, through which the voltage of the positive power bus is applied to

The first resistor and the base of the regulating first transistor, which is fully closed, since the voltage difference between their emitter and the base becomes minimal, equal to the voltage of the collector-emitter junction of the deeply saturated control second transistor.

When the regulating transistor is closed, the voltage on the load should decrease almost to zero, but this does not happen, as the compensating third transistor starts working, which opens because the base-emitter is applied to its junction through the resistor of the second chain first transistor. The degree of opening of the compensating third transistor is determined by the voltage stabilizing the second zener diode, because the compensating third transistor is connected according to the emitter follower circuit for which the output voltage is approximately equal to the input voltage on the base, which is chosen to be approximately equal to the normal voltage of the power source. When the normal voltage of the power supply is restored, the circuit returns to its original state, in which the compensating third transistor is completely closed.

A disadvantage of the known device is the low reliability caused by the malfunction due to the failure of the regulating and compensating transistors during a short circuit. In case of accidental closure of the output output of the device to the common bus, the regulating transistor burns out with the flowing short circuit current. After the control transistor burns out, the short-circuit current passes to the compensating transistor and leads to its failure. Thus, an accidental short circuit disables the entire device, which reduces the operational reliability of the device.

The aim of the invention is to increase operational reliability by maintaining operability when exposed to short circuits.

A matched pair of transistors by the conductivity type, coinciding with the control second transistor, a fourth transistor by the conductivity type, coinciding with the compensating third transistor, the second and third resistors, and a stelititron, and the anode

Zener diode is connected to the first output pin, and the Zener diode cathode is connected simultaneously to the integrated transistor base of a matched pair of transistors and through the second resistor to the cathode zener diode of the first threshold circuit, to which the combined emitters of the transistor of the matched pair of transistors are connected, and the collector of one transistor of the matched pair transistors are connected to a common conductor, and the collector of the other transistor of the matched pair of transistors is connected to the base four This transistor is directly connected to the common conductor through the third resistor, while the emitter of the fourth transistor is connected to the common conductor and the collector is connected to the base of the compensating third transistor.

In the event of a short circuit, the regulating first transistor is closed by the control second transistor and the third transistor is locked by the fourth transistor due to current flowing through the second resistor and, respectively, through the transistor of the matched pair of transistors and a punctured zener diode. This kind of transponder saves

operability of the device after removal of the short circuit. The drawing shows; functional diagram of the device for protection against overvoltage.

An overvoltage protection device 1, connected to the power supply 3, comprises a regulating first transistor 4, a controlling second transistor 5, a first resistor b and a threshold first chain 7 consisting of successively connected resistors 8 and 9 and a zener diode 10 the same first collector-emitter junction of the first 4 and second 5 transistors are interconnected and are intended to be connected to the first output of the power supply 3, the second collector-emitter junction of the first transistor Ora 4 is designed to connect to the first output of load 2, and the base of the first transistor 4 is connected to the first output of the first resistor 6, the second output of which, connected to the first end of the first chain 7, is designed to be connected to the second load 2 and power supply 3.

The device has a compensating third transistor 11 and a second threshold circuit 12 consisting of

series-connected resistor 13 and zener diode 14. The second terminal terminal of the first chain 7 is connected to the first terminal of the collector-emitter junction of the second transistor 5, and its average output

- with the base, the second transistor 5, the second output of the collector-emitter junction of which is connected to the base of the first transistor 4. The collector of the third transistor 11 and the first terminal output of the second chain 12

0 is connected to the first output of the collector-emitter junction, and the emitter of the third transistor 11 is connected to the second output of the collector-emitter junction of the first transistor 4, the middle output of the second circuit 5 of the kidney 12 is connected to the base of the third transistor 11, and its second end terminal is connected to the second output first resistor. Regulating the first transistor, 4 is made of a composite of two transistors.

In addition, the device includes a matched pair of 15 transistors consisting of transistors 16 and 17, the bases of which are connected and connected via the second resistor 8 to the cathode of the zener diode of the first threshold chain 7, to which the combined emitters of transistors 16 and 17 are connected. (16) of them are connected to the common conductor, and

0 the collector of the second (17) is simultaneously through the third resistor 19 to the common conductor and the base of the fourth transistor 20. The emitter of which is connected to the common conductor, and the collector to the base of the compensating third transistor 11, the Zener diode 21, an anode connected to the output terminal of the device, and the cathode - to the combined bases of the matched pair of 15 transistors.

0 The device works as follows.

Under normal voltage of power supply 3, transistor 5 is closed, since Zener diode 10 has a threshold for opening higher than normal voltage of the power supply. The current in the base circuit (transition emitter - base, resistor 9, zener diode 10) of transistor 5 is absent, and therefore there is no collector current. Regulatory

0, the transistor 4 is open and is in deep saturation mode (Uke 0.2-0.5 V) due to the base current flowing through the emitter-base junction and the resistor 6 from the positive to the negative power bus. Power

5, the saturation can be provided arbitrarily deep since it is determined by the resistor 6, the magnitude of which is not limited. When the transistor 4 is open, the transistor 11 is completely closed, since

The base-emitter junction through resistor 13 applies a low voltage OKe of the regulating transistor 4. As a result, at normal voltage of the source 3, the load 1 is supplied with minimum voltage losses (power dissipation) on the regulating transistor 4, i.e. with high efficiency.

When the voltage of the power supply increases (voltage surge) up to about the maximum allowable for load 2 magnitude, Zener diode 10 breaks through and a current appears in the chain 7, creating a voltage drop across the resistor 8. This causes the transistor 5 to open to deep saturation. which voltage of the plus power bus is applied to the resistor 6 and the base of the transistor 4, which is completely closed, since the voltage difference between their emitter and the base becomes minimal, equal to the voltage OKe of the deep saturated transistor 5. 4 and the closed transistor voltage across the load must allowed to lower to near zero. However, this does not occur, since a transistor 11 is activated, which opens, since the base-emitter is applied to its transition through a resistor 13 and the voltage drop of the fully closed transistor 4 is applied.

The degree of opening of the transistor 11 is determined by the stabilization voltage of the Zener diode 14, since the transistor 11 is connected according to the emitter follower circuit, for which the output voltage is approximately equal to the input voltage at the base. This voltage is chosen approximately equal to the stabilization voltage of the Zener diode 10, i.e. practically the same type of stabilizer is used. Therefore, for any magnitude of the surge voltage of the power source, the voltage at load 2 remains approximately equal to the normal voltage of the power source. The stability of the voltage across the load is determined by the stability of the zener diode in the temperature range and with changing load magnitude. The transistor 11 in all cases drops the voltage equal to the magnitude of the excess voltage of the source relative to the normal supply voltage.

When the normal voltage of the source is restored, the circuit returns to its original state, in which the transistor 11 is completely closed. With a short circuit load 2, i.e. the output terminal of the device to the common conductor, the zener diode 21 is punched through and through the resistors 8, 9 and 18 and the current flows. Current flowing

through a resistor 18, creates a voltage drop at which transistors 16 and 17 of the matched pair are opened.

The current flowing through the resistors 8 and 9 and the open transistor 16 creates a voltage drop across the resistor 8, which causes the transistor 5 to open to deep saturation, through which the positive bus voltage is applied to the resistor 6 and the base of the transistor 4, which is fully closed, since the voltage difference between the emitter and the base becomes minimal, equal to the voltage of the collector-emitter of the deep saturated transistor 5. When the transistor 4 is closed, the voltage on the load 2 decreases to zero. The current flowing through the resistors 8 and 9, the open transistor 17 and the resistor 19 creates a voltage drop on the latter, which introduces the transistor 20 into deep saturation, which completely covers the compensating third transistor 11.

Therefore, in the event of a short circuit, the load 2 simultaneously closes the regulating first transistor 4 and the compensating third transistor 11, and this is protected from the short circuit current. When the short circuit is eliminated, the circuit returns to its original state.

Thus, the invention maintains the operability of the device in case of a short circuit of the load and self-restores it to its original state after removing it, which allows to increase the operational reliability of the device. The use of the invention allows to create highly reliable power sources, and the elements introduced into the circuit are easily realized in microelectronic design.

Claims (1)

Invention Formula Device for protection against overvoltages of load according to auth.St. No. 1339742, characterized in that, in order to increase operational reliability by maintaining operability under the effect of a short circuit, a matched pair of transistors in the conductivity type, coinciding with the control second transistor, is introduced into it, the fourth transistor in the conductivity type, coinciding with the compensating third transistor, the second and third resistors and the zener diode, the anode of the zener diode is designed to be connected to the first. output of the load, and the cathode of the zener diode is connected simultaneously to transistors of matched pairs of transistors and through the second resistor to the cathode the zener diode of the first threshold chain to which the combined emitters of transistors of a matched pair of transistors are connected, the collector of one transistor of the matched pair of transistors is connected to a common conductor, and the collector of the other transistor of a matched pair of transistors is connected to the base of the fourth transistor directly, and to the common conductor through a third resistor, the emitter of the fourth transistor is connected to the common conductor, and the collector is connected to the base of the compensating third transistor.