SU1631526A1 - A c voltage stabilizer - Google Patents

Abstract

The invention relates to the secondary power supply sources of electronic equipment. The aim of the invention is to simplify. The diode-transistor regulating element 1 is controlled either from the output of the pulse-width modulator 6, the input of the amplitude value of the input voltage connected to the output of the sensor 10, or by the control transistor 18, whose input is connected to the output of the sensor 12 of the effective value output voltage As long as the input voltage amplitude is less than the value specified by the reference source 8, the pulse-width modulator 6 maintains the diode-transistor control element 1 in a saturated state. When the input voltage amplitude exceeds a predetermined value, the pulse-width modulator 6 is turned off and the diode-transistor control element under the action of the output current of the control transistor 18 passes into the active operating region, and its conductivity is maintained at the level necessary to stabilize the effective value of the output voltage wives 2 Il. with s

Description

The invention relates to electronics and can be applied to power general-purpose radioelectronic equipment, in particular to power the glow circuits of high-power generator tubes in transmitters.

The purpose of the invention is to simplify the variable voltage stabilizer.

Fig. 1 is a block diagram of a voltage regulator; in fig. 2 - time diagrams that show his work.

The alternating voltage stabilizer contains a diode-transistor regulating element 1, consisting of diodes 2 and 3 and transistors 4 and 5, and a pulse-width modulator (PWM) 6 at the comparator 7, the source 8 of the reference voltage and the amplifier 9 power , voltage amplitude sensor 10, transformer 11, current voltage value sensor 12, input 13 and output 14 outputs and common bus 15, resistor 16 full-wave rectifier 17 without a filter, regulating pn-p transistor 18, as well as the first 19 and second 20 diodes. In the base circuit of transistor 18 is included resistor 16.

The PWM input 6 is connected to the output of the sensor 10 of the amplitude voltage value. The input of the sensor 12 to the effective voltage value is connected to the output terminal 14 and the common bus 15. Diode-transistor control element 1 is connected between the input 13 and output 14 pins. The PWM 6 output through the first diode 18, connected in the conductive direction, is connected to the control input of the diode-transistor control element 1, i.e. with interconnected bases of transistors 4 and 5. The output of the sensor 12 of the effective voltage value is connected to the base of the control transistor 18. The emitter of the latter is connected to the output of the introduced full-wave rectifier 17, whose input through the transformer 11 is connected in parallel to the diode-transistor control element 1. The collector of transistor 18 through the second diode 20 connected in the conducting direction is connected to the control input regulating element 1. A voltage amplitude sensor input is connected between input terminal 13 and a common bus. General, the PWM 6 terminals of the full-wave rectifier 17 without a filter and the sensor 12 of the effective voltage value are connected to the common control terminal of the diode-transistor control element 1.

The variable voltage regulator operates as follows.

At the moment of switching on elements 7-9 into PWM 6, the supply voltage EC is applied, the regulating element 1 is locked, and the voltage at the output of the sensor 10 of amplitude value and at the inverting input of the comparator 7 is zero. Under these conditions, under the action of the reference voltage the voltage of the source 8 entering the non-inverting input of the comparator 7, voltage appears at its output 1. It is amplified in a non-inverting amplifier

9 power and through the diode 19 enters the bases of transistors 4 and 5. This ensures saturation of that of transistors 4 or 5, in which the collector has a positive potential in this half-period of the network voltage.

As a result, a voltage appears at output terminal 14. Sensor output

Amplitude value, made, for example, in the form of a full-wave rectifier without a filter, appears to be the voltage of the sinusoidal half-periods (Fig. 26). As long as the voltage amplitude does not exceed the specified nominal value, the voltage at the output of the sensor 10 of the amplitude value does not exceed the reference voltage of source 8 (Fig. 2b. Dashed lines). As a result, the voltage at the output of the PWM 6 (i.e., at the output of the comparator 7) maintains level 1 during each half period of E (Fig. 2c, dashed lines). Therefore, transistors 4 and 5 are saturated for the same half periods.

If the voltage amplitude exceeds a predetermined value determined by the reference voltage, then in the output voltage of PWM b dips appear, in time corresponding to the central parts of each half period of the network (Fig. 26, c, solid lines). As a result, during these intervals with a duration of TI, the bases of transistors 4 or 5 do not receive voltage from the PWM output 6. Thus, the amplitude value of the output voltage is stabilized at a predetermined level (Fig. 2e). Accordingly, the voltage on the regulating element 1 during the time interval P increases, acquiring the form of bipolar pulses of EC with duration TI (Fig. 2d). This voltage through the transformer 11 is fed to the rectifier 17, the voltage at its output takes the form of unipolar pulses Ei7, which are fed to the emitter of a pn-p-transistor 18 (Fig. 2e). At the same time on its base from the output of the sensor 12 current

a voltage value is supplied to the control voltage proportional to the actual value of the output voltage. If the effective value of the output voltage under the action of destabilizing factors begins to increase relative to the specified nominal value, then the output voltage of the sensor 12 of the effective voltage value also increases, so the collector current of a pnpr transistor 18 passing through the diode 20 and base-emitter transitions of transistors 4 and 5 decreases. These transistors during the interval Ti work in active mode; a decrease in base current causes them to be blocked. As a result, the effective value of the output voltage starts decreasing until it reaches the specified nominal value; The shape of the output voltage of the EVs takes the form shown in FIG. 2nd.

Claims (1)

Invention Formula An alternating voltage stabilizer containing a diode-transistor regulating element, the first power output of which is connected to the input terminal, a pulse-width modulator, an input connected to the output of the voltage amplitude value sensor, a transformer and an effective voltage value sensor, the input of which is connected to the output output and a common bus, characterized in that, for the purpose of simplification, a full-wave rectifier without a filter is inserted in it that controls the pnp transistor, the first and second diodes, and the second power output of the diode-transistor control element is connected to output terminal, pulse width output the modulator through the first diode connected in the conductive direction is connected to the control input of the diode-transistor control element; the output of the sensor of the effective voltage value connected to the base of the regulating pnp transistor; the emitter of which is connected to the output of a full-wave rectifier whose input through a transformer is connected in parallel with a diode-transistor regulating element; the collector of the regulating pnp transistor is connected via a second diode connected Diode transistor regulating element input, voltage amplitude sensor input connected between input terminal and common bus, common terminals of pulse width modulator , full-wave rectifier without filter and current sensor the voltage values are connected to the common control terminal of the diode-transistor control element. FPO PP e) tf 2 / J