SU809442A1 - Power amplifier protecting device - Google Patents

Description

(54) DEVICE ZMDITES OF POWER AMPLIFIER

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This invention relates to electrical engineering and can be used in output stages of power amplifiers. and automation devices.

A power amplifier protection device is known, the switching elements of which are connected in series between the power supply buses. The device contains reverse link formers, the outputs of which are connected to the inputs of the switching elements connected to the negative and positive buses of the power supply source, respectively, Sch.

However, such a device does not protect the output amplifiers from short circuits in the load and at the output of key elements.

The purpose of the invention is to protect against short circuits in the load and to reduce the through currents.

This goal is achieved by the fact that in the protection device of a power amplifier, the switching elements of which are connected in series between the power supply buses containing feedback drivers, the outputs of which are connected to the inputs of the switching elements connected to the t-1 sine and plus power supply buses, respectively, the reverse drivers The connections are made on the threshold elements and are connected by their inputs to the outputs of the switching elements via rectifiers.

FIG. 1 is a schematic electrical diagram of the device; FIG. 2 is a sequence diagram explaining the operation of the device.

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The device contains switching elements 1-4, power supply busbars 5 and 6, feedback drivers 7 and 8, rectifiers 9 and 10, resistor 11, diodes 12 and 13, stabilizer 14 and 15, inverter 16, diode 17, resistor 18, diodes 19 and 20, resistor 21 and load 22.

The device works as follows.

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Let the switching element 4 be open in the initial state, and the switching element 3 is closed, while the positive potential from the resistor 11 is bounded by an open diode

5 12 and the switching element 4, and the input of the switching element 3 is bridged through the diode 13, the diode 12 and the switching element 4. The Zener diode 15 is not pierced, the input

Claims (1)

0 of the inverter 16, the prestarting zero voltage and the rectifier 10 are maintained in the locked state. When control signals are received for locking and unlocking the switching elements 4 and 3, the switching element 4 cannot be instantly closed due to an overcharge in the base. Therefore, although the diode 13 is locked by the control signal, diode 12 is still open due to overcharging and continues to shunt the input of the switching element 3. After the excess charge is absorbed, the diode 12 is locked and unlocked by the switching element 3. At the same time, through the diode 17 and the resistor 18 opens Zener diode 15, a single potential appears at the input of inverter 1, and diode 19 through inverter 16 shunts the input of switching element 4, duplicating its locking through diode 20. At the next moment, the control signals go to unlock and lock switching elements 3 and 4. At the same time, zener diode 15 remains open through diode 17 and resistor 18 for the time of dissipation of excess for a row from the base of switching element 3, while switching element 4 remains closed after locking diode 17 and Zener diode 15 device returns to the initial state. The operation of the device is explained in the sequence diagram shown in FIG. 2, where 3 and T are the current plots at points a and b of FIG. 1, the output plots of the output current of the switching elements 3 and 4 without feedback) lj and) are the current plots at points 3 and 4 generated by feedback kgsos The output current output diagrams of the switching elements 3 and 4 are based on feedback. In the event of a short circuit at the output of the switching element 4, a diode 12 is automatically opened, the input of the switching element 3 is shunted and it is locked. In the event of a short circuit at the output of the switching element 3, the diode 17 is unlocked and the Zener diode 15 is punctured / the input of the switching element 4 is bridged through the diode 19 and the output of the inverter 16. Similarly, the protection against short circuits in the load is performed. Thus, in the proposed device, at low hardware costs, without using reactive elements, complete protection against through currents in short circuits in the load or at the outputs of the switching elements 1-4 is provided. Such a device can be widely used in the construction of amplifiers for tracking electric drives, robots and manipulators. Claims The power amplifier protection device, the switching elements of which are connected in series between the power supply buses, contains feedback drivers, the outputs of which are connected to the inputs of the switching elements connected to the negative and positive power supply buses, respectively, characterized in that protection against short circuits in the load and reduction of through currents, the feedback drivers are made on the threshold elements and are connected by their inputs to the switch outputs rectifying elements through straighteners. Sources of information taken into account during the examination 1. Leonenko L.I., Pavlova L.P. Bridge controllers with through-current protection. In the book. Electronic technology in automation, vol. 6, M., Soviet Radio, 1974.