SU1201990A1 - Rectangular a.c.voltage-to-sine voltage converter - Google Patents

Abstract

AC VARIABLE VOLTAGE CONVERTER FOR SINUSOIDAL CONTAINING, containing n series-connected aperiodic RC-links, the first and the last of which are connected to the input and output gates, respectively, in order to expand the functionality by increasing the frequency range to transform the transducer, thereby increasing the functionality by increasing the frequency range and transforming, thereby increasing the functionality by increasing the frequency range and transforming, thereby increasing the functionality by increasing the frequency range and transforming, thereby increasing the functionality by increasing the frequency range and transforming, transforming the functionality by means of increasing the frequency range is redesignable by increasing the functional capabilities by increasing the frequency range. each of the aperiodic RC-links is made according to the integrator scheme, which includes series-connected resistor Optocouplers and operational effort A capacitor-shunted cable was added, and a regulating unit was additionally introduced, the input of which is connected to the output terminal, and the output is connected to the input circuits of resistor optrons.

Description

one

The invention relates to electrical engineering and can be used as a sinusoidal oscillator with controlled frequency in automatic control systems for electrical and radio equipment.

The aim of the invention is to enhance the functionality by increasing the frequency range of the voltage to be converted.

The drawing shows the basic electrical circuit of a rectangular-to-sinusoidal variable voltage converter.

The device contains serially connected aperiodic RC links 1 and 2 and regulating node 3. The input of aperiodic RC link 1 is connected to the input terminal 4 of the device, the output of the aperiodic link is the 2nd output output view of device 5 and the input of the regulating node 3.

Aperiodic R C-link 1 is absolute according to the integrator scheme and contains a resistor optocoupler 6, a capacitor 7 and an operational amplifier 8. The same scheme includes an aperiodic RC-link 2 containing a resistor optocoupler 9, a capacitor 10 and an operational amplifier 11. As Aperiodic RC-units 1 and 2 can be applied and inertial units - active or passive. The input circuits of the resistor optocouplers are connected in series (it is possible and their parallel connection and connected to the output of the regulating node 3.

The regulating unit 3 provides a smooth increase or decrease in the current through the input circuits of the resistor optocouplers 6 and 9 with the amplitude of the sinusoidal voltage at the output of the device with a correspondingly greater or less than a predetermined value. It contains a series-connected Zener diode 12, a cumulative cell made on diode 13, resistor 14, capacitor 15, large-scale amplifier 16 (non-inverting, with a constant gain factor) and resistor 17 connected by a first output to terminal 18 of the power supply. The input of the regulating unit 3 is the gap between the cathode of the Zener diode 12 and the common

20I9902

length, output - the gap between the second step of the resistor 17 and the output of the scale amplifier 16. The device operates as follows; in a way.

The rectangular AC voltage is applied to the input terminal 4. At the moment the device power is turned on, the voltage on the capacitor 15 is zero, therefore the voltage at the output of the scale amplifier 16 is also zero, and the maximum current flows through the circuit: power terminal 18 - resistor 1715 the input circuits of the resistor optocouplers 9 and 6 are the output of the large-scale amplifier 16. At the same time, the resistances of the resistor optocouplers 6 and 9, which are equal at the moment of turning on the power to the dark (high) resistance,

decrease, approaching the light (low) resistance. The transmission coefficient of each of the aperiodic of each of the aperiodic

25 RC links 1 and 2 are defined by

K, ("1 K, (SO) -J

 2 iTc ()

where 00 and 1 circular frequency and

AC input frequency; R is the resistance of the output circuit of the resistor opto-in at 6 or 9; C - capacitor capacitance 7

or 10.

The transfer ratio of the entire device

K (s) K, (w). Kg ((about g 1 N2

(2) iTirfR c)

In accordance with expression (2), as the resistors Я I of resistor optocouplers 6 and 9 decrease, the transmission coefficient, and hence the amplitude of the output voltage of the device, increases and reaches the voltage of the zener diode. At the same time, at the time points corresponding to the vertices of the positive half-waves of the output sinusoidal voltage, current pulses flow through Zener diode 12, diode 13, resistor 14, capacitor 15, as a result of which the capacitor 15 is charged. the voltage across it and at the output of the scale amplifier 16 increases the current through the input circuits of the resistor optocouplers 6 and 9 decreases, and the processes proceed in the opposite direction. As a result, due to the presence of negative feedback from the output of the device to the inputs of aperiodic links 1 and 2 through the regulating node 3, the amplitude of the sinusoidal voltage or output of the device stabilizes at the level of the voltage of the zener diode 12. When the device is input (up to several tens of times), the transmission coefficient of the device, which is inversely proportional to i in accordance with the expression (.2), initially decreases, as a result of which the amplitude of the output voltage of the device the breakdown of the Zener diode 12 becomes less, therefore the flow of current pulses through the Zener diode 12 stops, the capacitor 15 is not charged, and discharges, the voltage across it and at the output of the scale amplifier 16 decreases, the current through the input circuits of resistor optocouplers 6 and 9 increase 90% , the resistance of the latter decreases, the transmission coefficient of the device increases until then. until the amplitude of the output sinusoidal voltage again reaches the voltage of the breakdown of Zener diode 12. Thus, at any frequency of the input signal, the amplitude of the sinusoidal voltage at the output of the device is automatically set equal to the specified value. The number of aperiodic ftC units of the device can be more than two, depending on the required harmonic suppression ratio, which can be increased by increasing the number h. From the expression (2 it follows that. To maintain the transmission coefficient K (6j) unchanged when the input signal frequency increases some number of times, the resistance R of the resistor optocoupler should decrease as many times, since the operating frequency range of the device corresponds to the ratio of resistance adjustment resistor optocouplers.

Claims (1)

RECTANGULAR VOLTAGE CONVERTER TO SINOUSAL FORM, containing D series-connected aperiodic RC-links, the input of the first and the input of the last of which are connected respectively to the input and output terminals, characterized in that, in order to expand the functionality by increasing the frequency range of the convertible voltage, each of the aperiodic RC-links is made according to the integrator circuit, including a resistor optocoupler and an operational amplifier connected in series, for untirovanny capacitor, and further introduced regulating unit 'having an input coupled to the output terminal, and the input circuits The output resistor optro- · SU „„ 1201990