SU1527627A1 - Unit for supply of different-polarity voltages - Google Patents

Abstract

The invention relates to electrical engineering and can be used to power various electronic devices. The purpose of the invention is to provide protection for each of the stabilizers in the event of a short circuit of any of the potential terminals on the common bus, as well as the independent activation of the stabilizers at any time. When one of the stabilizers is turned on, the protection transistor 8 or 9 of the non-switched stabilizer remains closed. When the input voltage is applied to another stabilizer, its protective transistor 8 or 9 remains closed, which contributes to the opening of the regulating element (RE) 1 or 2, the appearance of voltage at the output of the stabilizer and the current in the load 5. Thus, turning on one of the The stabilizers do not cause the re 1 or 2 stabilizers not to be locked, the latter can be switched on in the usual way at any time. When the output terminal of any stabilizer to the common bus is short-circuited, almost all the current from the current stabilizer 16 or 17 will pass through diode 18 or 19, which will open the transistor 8 or 9 and close the ER 1 or 2. This will protect the stabilizer. 1 hp f-ly, 1 ill.

Description

The invention relates to electrical engineering and can be used to power various electronic devices.

The purpose of the invention is to ensure the protection of each of the power supply voltage regulators of multi-pole voltages in the event of a short scan of any of its potential terminals on the common bus, as well as independently switching on the stabilizers at any time.

The drawing shows a diagram of a unit of power supply for bipolar voltages.

The power supply unit of bipolar voltages consists of two stabilizers of different polarity, each of which contains a regulating element 1 (2) and a current sensor 3 (4), connected to the corresponding power bus in series with the load 5, the control measuring and amplifying unit The 6 (7) input is connected to the output pins of the stabilizer, and the output to the control input of the regulating element 1 (2). The protective transistor 8 (9) is connected to the common point of the current sensor 3 (4) and the stabilizer output, emitter, the collector to the control input of the regulating element 1 (2), and the base to the midpoint of the divider 10 (11) voltage. Diode 12 (13) is connected in parallel with the output terminal in the opposite direction. Resistor 14 (15) is connected to the output of the stabilizer with one lead.

A current stabilizer 16 (17) is connected in parallel to the input terminals of the stabilizer, the output to the first output of the voltage divider 10 (11) and through the forward junction of the diode 13 (19) to the circumference of the current sensor 3 (4) and the regulating element 1 (2). A diode 20 (21) is connected in the forward direction parallel to the output pins of the stabilizer through a resistor 14 (15) to the common connection point of which and the diode 20 (21) a second output of the 10 OO voltage divider of the opposite polarity is connected,

As diodes 20 and 21, LEDs can be used to signal the normal operation of each of the stabilizers.

The power supply operates as follows.

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When one of the stabilizers is turned on by its output voltage, a diode 12 or 13 opens at the output of the non-switched stabilizer (artificial short circuit mode), i.e. to the emitter of the protective transistor 8 or 9 with respect to its base, the opening voltage of the forward-displaced diode 12 or 13 is applied,

However, the closed-circuit transistor 8 or 9 of an unpowered stabilizer remains closed at the time it is turned on, since the base voltage across an open diode 20 or 21 connected by the first stabilizer is applied to its base through the second shoulder of the divider 10 or P. In this case, the potential difference between the base and the emitter of the protective transistor 3 or 9 is close to zero.

If we now apply the input voltage to another stabilizer, the current stabilizer 16 or 17 begins to supply the circuit with a stable current: the first through a displaced diode 18 or 19 junction, the sensor 3 or 4 currents, the load 5, and the second divider 10 or .11 through a resistor 14 or 15.

At the same time, the sum of the voltage across diode 18 or 19, sensor 3 or 4 and the first shoulder of divider 10 or II is not enough to open the protective transistor 8 or 9. The latter remains closed, which contributes to the opening of the regulating element 1 or 2. the output of the stabilizer and the current in the load 5. As soon as the current mentioned exceeds half the load current 5, the diode 12 or 13 closes, the artificial short circuit disappears and the output voltage + b1x rises to its nominal value, since it is a current equal to half that advancing a load stabilizer, flows through the diode 12 or 13, the shunt regulator output lagging.

The inclusion of one of the stabilizers does not lead to the locking of the regulating element of the non-included stabilizer, and the latter can be switched on in the usual way at any time.

When the output pin of any of the stabilizers to the common bus is short-circuited, the diode 18 or 19 starts

bypass divider 10 or 11 voltage, i.e. almost all of the current from the current stabilizer 16 or 17 passes through the diode 18 and 19, which leads to the disappearance of the locking transistor 8 or 9 of the voltage on the first arm of the divider 10 or 11, the transistor 8 or 9 opens and closes the regulating element 1 or 2.

Thus, in the proposed device, protection against short circuits of the output of each of the stabilizers to the common bus is provided.

Claims (2)

1. A power supply unit for bipolar voltages containing two stabilizers of different polarities, each of which consists of a regulating element connected in series to a corresponding power bus and a current sensor controlling the measuring and amplifying unit, the output of which is connected to the regulating input of the regulating element, and the input to the output pins of the stabilizer, the first and second output pins of the stabilizers, which are potential pins, are connected to the pins for connecting the load, and the third and fourth stabilizers th output terminals - a common bus, a protective transistor, the emitter of which is connected to the common point of the current sensor and the output terminal, the collector - to the control input 0 regulating element, and the base - to the midpoint of the voltage divider. the first diode connected in parallel to the output of the stabilizer in the opposite direction, characterized in that, in order to protect each of the stabilizers in the case of a short baking of any of the potential terminals on a common rail, as well as independently enable the stabilizers at any time, each of the stabilizers A current stabilizer, second and third diodes and a resistor are introduced, the current stabilizer being connected in parallel to the input pins of the stabilizer and the output to the common point of the first output g the voltage of the second diode, biased in the forward direction and connected by another output to the common point of the regulating element and the current sensor, the chain consisting of series-connected resistors and the third diode connected in the forward direction is connected in parallel to the output pins of the stabilizer, the resistor is connected to the potential output, and a second output of the voltage divider of the opposite polarity is connected to the common point of the resistor and the third diode. 2. The power supply unit according to claim 1, which is based on the fact that in each of the stabilizers an LED is used as the third diode. 0 five 0 five