SU683019A1 - Switching and protection system of a voltage source - Google Patents

Description

move 12 devices. The base of transistor 10 of key 9 is connected to the output of trigger 5. Dynamic converter 8 runs on two transistors 13 and 14 connected in a common emitter circuit, the bases of which are connected to the dynamic input:; l, and the collectors are connected to the outputs of the dynamic converter and through the respective capacitors 15 and 16 to the combined capacitors. The switching device and the protection of the power source works as follows. With a rated current flowing through the conductive busbar 3, 4, the voltage across the measuring resistor 2 is equal to the value at which the threshold amplifier 1 is in its initial locked state. At the same time, transistors 5 and 7 of trigger 5 are kept locked. Transistor Key 9 is also locked. The control signal is not applied to the input of the converter 8, and transistors 13 and 14 are locked. The integrating capacitor 15 is discharged, and the integrating koidevsator 16 is charged before the voltage of the auxiliary power source vs, - The voltage at the output 12 of the device is equal to E ngp, which corresponds to the signal to turn on the source of the controller. If “through the conductor bus 3, 4 exceeds the permissible value, a la- rimer, due to a short circuit at the output of the voltage source, then the voltage across the measuring resistor 2 o is indicated above the threshold of the amplifier. In this case, the threshold amplifier 1 generates a signal that is fed to the trigger start input 5. The trigger transistor 6 is turned on instantly, and the transistor / is opened with a delay. The delay time is determined by the charge time of the integrating capacitor 15 through the collector resistor of transistor 6 to the voltage to unlock the base-emitter junction of transistor 7. When unlocking transistor 7, trigger 5 switches to another stable state at which both transistors 5 and 7 are unlocked . Simultaneously with the transistor 7 of the trigger 5, the transistor 10 of the switch 9 is turned on. The integrating capacitor 16 is discharged through the transistor 10, and the voltage at the output 12 of the device decreases to zero. The zero potential at the output 12 of the switching and protection device OPTIMIZES the voltage source off signal. After eliminating overcurrent (e.g., short circuit and output of the source), the operator preliminarily sends a control signal in the form of a sequence of positive amplitude emulsions to the input of the dynamic converter 8. Transistors 13 and 14 are unlocked with positive pulses. The storage capacitor 15 is discharged through the transistor 13. In this case, the transistor 7 of the flip-flop 5 and the transistor 10 of the switch 9 are locked. The trigger 5 returns to its original state, with the motor both transistors 6, 7 locked. The storage capacitor 16 is kept discharged due to the unlocking of the transistor 14 until it is saturated with control pulses. Thus, when the sequence of positive pulses and the input of the dynamic converter 8 is applied, the flip-flop 5 is reset, and the output 12 of the switching and protection device has a zero potential corresponding to the source turn-off signal. To form a switching device and protect the voltage source switching signal, the operator stops the pulses to the dynamic converter 8. At the same time, the transistors 13 and 14 are locked. The integrating capacitor 15 is kept discharged, and the integrating capacitor 16 is charged through the collector resistor of transistor switch 9. The voltage at output 12 of the switching and protection devices increases from pool to voltage jGae. which corresponds to the appearance of a voltage source turn on signal. Thus, the switching and protection device provides the remote control of the state of the power source by means of the pulse sequence. Moreover, if necessary, the pulse control of the switching and protection device can be carried out in a galvanic position. The proposed device .commutation and protection has increased noise immunity from false alarms of protection when the voltage source is turned on. When the voltage source is switched on, it turns out to be loaded on the discharged capacitance of the filter, which causes an inrush current whose magnitude exceeds the nominal value. During the inrush current, the threshold amplifier 1, naturally, generates a trigger trigger signal 5. At this time, the triangle 6 is unlocked. The constant charge time of the I1 integrating capacitor 15 is chosen so large that the integrating capacitor 15 cannot be charged before the threshold of unlocking the transistor 7 during a current surge. Therefore, the transistor 7 is kept locked, and a simple alarm signal does not come to the input of the switch 9. The proposed device also has a high noise immunity while reducing the power consumption of the control circuit //. This is achieved both by dynamic conversion and by galvanic development, the implementation of which is also facilitated by impulse control.

Thus, in principle, the proposed device for switching and protecting a voltage source solves the problem of remote-impulse control with galvanic isolation of a voltage source while simultaneously increasing the noise immunity of automatic switching and protection against overloads of the voltage source.

Claims (2)

1. The device is a commutation. And protection of a voltage source, containing a measuring resistor, connected to a controlled conductor bus and connected to two inputs of a threshold amplifier, the output of which is connected to the trigger trigger input, characterized in that, in order to increase the noise immunity and. reduction of power consumption; a dynamic converter and a key performed on the transistor according to a common emitter circuit are additionally introduced into the device, while the input of the dynamic converter is connected to the control input laziness of the device, its outputs are connected respectively to the reset input of the above-mentioned trigger and the collector of the transistor key, connected to the output of the device, and the base of the transistor key is connected to the output of the trigger. 2. The device according to l. 1, characterized in that the dynamic converter made on two transistors included in the scheme with a common em, itter, the bases of which are connected to the input, and the collectors - to the outputs of the dynamic converter and through the corresponding capacitors to the combined emitters. Sources of information taken into account in the examination: 1. Shtilman V. I. Microelectronic voltage stabilizers, Kiev, Technique, 1976, p. 98, fig. 23. 2. Agapov I.V., Pitukha A.V. Electr. Protection of semiconductor power sources. Soviet radio, 1966, with. 123, fig. 80