SU845250A1 - Ac voltage-to-dc voltage converter - Google Patents

Description

one

The invention relates to converter technology and can be used in stabilized power sources to improve their dynamic properties.

AC / DC converters are known, made in the form of stabilized power supplies with a transformerless input p-3.

The low performance of these converters in processing changes in the input voltage is due to the fact that the input of the feedback unit is connected to an output filter having a large time constant.

The closest in technical solution is a converter containing a first rectifier connected in series of low frequencies, a smoothing filter, an inverter, an isolation transformer, a high-frequency rectifier and a filter - C1

converter output as well as an inverter control system containing interconnected control voltage generation unit and feedback unit consisting of a comparison node and a reference voltage source connected to one of the inputs of the comparison node, the second input of the comparison node being connected to the output of the converter |; 4.

The disadvantage of such a converter is low dynamic characteristics when exposed to disturbing influences from the input voltage side. The low dynamic characteristics are due to the fact that the input of the control system is connected directly to the output of the converter, after a smoothing factor, the time constant of which is chosen from the condition of smoothing the output voltage ripples and, consequently, should

be several times longer than the period of the inverter output voltage.

The aim of the invention is to improve the dynamic characteristics of the converter by increasing the speed of perturbing effects, as well as improving the speed of the conversion.

This is achieved by the fact that in a converter containing a low-frequency coupler connected in series, a smoothing filter, an inverter, an isolation transformer, a high-frequency rectifier and a filter forming the converter output, and an inverter control system containing interconnected control unit and a feedback unit, consisting of a reference node and a source of reference voltage, connected to one of the inputs of the comparison node, as well as a measuring element, output Yuchenny to the second of the inputs is connected directly to the output of the high-frequency rectifier.

In the described converter, a measuring unit that implements the principle of high-frequency polling, containing a capacitor connected sequentially to a control current generator, and a synchronization circuit (5 J and 6 j) could be used. The output value of this device is the pulse frequency, Carrying information about the magnitude of the measured voltage. When using such a measuring body in the described converter, a constant voltage pulse frequency converter is needed for comparing it with a constant reference voltage.

The measuring unit of the converter contains a capacitor with a discharge circuit connected in series to a controlled current generator, and the synchronization circuit is additionally equipped with a peak detector and a memory circuit sequentially connected to the control circuit, the output of which is connected to the control input of the memory circuit. synchronization circuits, and inputs of a controlled current generator.

discharge circuits and synchronization circuits are combined and form the input of the measuring organ.

Figure 1 presents the structural diagram of the proposed Converter in figure 2 - diagram of the measuring body; Fig. 3 shows diagrams explaining the principle of operation of the measuring organ with an open circuit in reverse communication; Fig. A shows the same, with a closed feedback circuit.

The proposed AC / DC converter contains a series-connected low-frequency rectifier 1, a smoothing filter 2, an inverter 3, a split-up transformer 4, a high-frequency rectifier 5 and a smoothing filter 6 forming the output of the converter 7, as well as an inverter control system 8 containing the connected between each other, the control voltage shaping unit 9 and the feedback unit 10, consisting of the comparison node 1 and the source of the reference voltage 12, connected to one of the inputs of the comparison node Eni P, as well as the measuring body 13, output 14 connected to the second of the inputs of the comparison node 11. The input 15 of the measuring body 13 is connected to the output of the high-frequency gate of the meter 5. The measuring body 13 contains connected in series an electric current generator 16, a capacitor 17 with a discharge circuit Yes 18, as well as a synchronization circuit 19 and interconnected peak detector 20 and memory circuit 21, the output of which forms the output 14 of the measuring element 13..K to the control input 22 of the memory circuit 21 is connected, the output of the circuit synchronization 19, and the inputs of the controlled current generator 16, the discharge circuit 18 and the synchronization circuit 19 are combined and form the input 15 of the measuring body 13.

Consider the principle of operation of the measuring body.

In detail, we first consider its operation with an open feedback circuit of the converter. In this case, the input 15 of the measuring body 13 from the output of the high-frequency rectifier 5 receives a sequence of pulses 23 with a constant duty cycle (say, 2), the amplitude of which is determined by the voltage at the input of the inverter 3. The output current of the controlled current generator 16 directly proportional to the amplitude of the pulses 23, therefore the charge rate of the capacitor 17 is also directly proportional to the amplitude of the pulses of the sequence of pulses 23. During the operation of each pulse, the capacitor 17 is charged to a voltage the rank of which corresponds to the average value of the voltage pulse. The input of the discharge circuit 18. Enters a sequence of pulses 23. With a zero potential at the input of the circuit of discharge 18 (i.e. during the pause between pulses of the pulse sequence 23}, the capacitor 17 is quickly discharged and the discharge circuit 18 maintains zero voltage before the next impulse of a pulse sequence 23 arrives. As a result, a pulse voltage 24 is formed on the capacitor I7, and the amplitude of each pulse voltage pulse 24 is proportional to the average value of the voltage of the corresponding imp 23. lsa pulsed voltage 24 is input to the peak detector 20. The voltage at the output 25 of the peak detector 20 is repeated to form the voltage on the capacitor 17 during periods 35

his charge. After discharge of the capacitor 17, the voltage 25 at the output of the peak detector 20 decreases due to the discharge of the capacitance of the peak detector 20, due to the non-ideality of the circuit elements (moreover, such a discharge may be provided for)

A pulse sequence 23 is applied to the input of the synchronization circuit 19. The synchronization circuit 19 generates a voltage 26 in the form of short pulses 27 that coincide with the falling edges of the pulses of the pulse sequence 23, and their duration is much less, for example, 2 times less than the pulse width of the pulse sequence 23.

The output voltage 25 of the peak detector 20 is fed to the input of the memory circuit 21, to the control input 22 of which pulses 27 of the pulse sequence 26 are output from the output of the synchronization circuit 19. At

The voltage 31 at its output tends to a constant value, and the output of the synchronization circuit produces a voltage 32. At the output of the bushing circuit 21, this produces a constant voltage 33 corresponding to the average pulse voltage of 29 a sequence of pulses 29,

Claims (6)

When the average value of the voltage at the output of the high-frequency rectifier 5 deviates from a constant value, the change in voltage 33 at the output 14 of the measuring body 13 occurs with a time delay not exceeding 1/2 the period of the output voltage of the inverter 3. For example, at the conversion frequency equal to 20 kHz, the delay is no more than 25 µs, and the time of perturbing effects proposed by the converter is determined by this figure. 4 this, at the output of the memory circuit 21, a voltage 28 is formed, the amplitude of which varies discretely (the change of the amplitude occurs when the pulse sequence 26 of each pulse 27 arrives at the control input 22) in accordance with the change in the amplitude of the voltage pulses 25. Thus, at the output 14 of the measuring body 13, a voltage 28 is generated, the amplitude of which corresponds to the average value of the voltage of each of the pulses of the pulse sequence 23 supplied to the input 15 of the measuring body 13 s output high-frequency rectifier 5. When the closed loop feedback stabilization occurs average value of the output voltage of the converter. For example, as the voltage applied to the input of inverter 3 increases, the amplitude of the pulses of the pulse sequence 29 at the output of the high-frequency rectifier 5 increases. At the same time, the pulse duration decreases. The charge rate of the capacitor 17 increases as the output current of the controlled current generator 16 increases, however the charging time decreases. Therefore, the amplitudes of the pulse sequence 30 at the input of the peak detector 20 and the pulse. Connecting the input of the measuring body to the output of the high-frequency rectifier, as well as the introduction of a peak detector and memory circuit into the measuring body, significantly improved the dynamic characteristics of the proposed converter compared to the prototype. So, if in the prototype, when the inverter output voltage frequency is equal to 20 kHz, the disturbing effects testing time is determined by the constant time of the output smoothing filter, which is 10-15 times longer than the period of the inverter output voltage (to ensure this voltage is sufficiently smooth) that is 500-750 µs, in the proposed technical solution, the speed is determined by the delay time of formation of the average value of the output voltage, which is 25 MKS, Claim 1, the Converter AC voltage to constant, containing connected in series low-frequency rectifier, smoothing filter, inverter, isolation transformer, high-frequency rectifier and filter that forms the output of the converter, as well as an inverter control system containing interconnected voltage control unit a feedback unit, consisting of a comparison node and a voltage source, connected to one of the inputs of the comparison node, as well as a measuring element, the output is connected It is connected to the second of the input nodes of the comparison node, which differs in that, in order to improve the dynamic characteristics of the converter by increasing the speed, testing of disturbing influences from the AC network, the input of the measuring organ is connected to the output of the high-frequency rectifier. 2. The converter according to claim 1, the measuring body of which contains a series-connected controlled current generator, a capacitor with a discharge circuit, and a synchronization circuit, characterized in that, in order to increase the speed of the converter, it is additionally equipped with series-connected peak detector and a memory circuit, the output of which forms the output of a measuring organ, wherein the output of the synchronization circuit is connected to the control input of the memory circuit, and the inputs of the controlled current generator, the discharge and synchronization circuits are combined and form an input, measure-. body. Sources of information taken into account when examining 1.Veresov G.P., Smurkov Yu. L. Stabilized sources of radio equipment.- M., Energie, 1978, p.28. 2.Skubko V.A., Melnikov A.V. Method of analysis and calculation of electrical characteristics of secondary power sources with intermediate frequency conversion. In the book. The problems of miniaturization and unification of the VIP REA. M., 1979, p. 35 3. Gals B. K., Bulyk V. M. Miniaturization and unification of VIP peripherals of computers, in the book. Problems of miniaturization and unification of VIP CEA. -M., - 1979, p. 140-145, 4. Guliy V, D., Zhuikov V, I. Stability of power supply device with pulse-width modulation. In the book. Methods and means of converting electrical energy parameters. Kiev, Naukova Dumka, 1977, p. 57 (prototype) 5.Mart Shin A.I., Shakhov E., K., Shlndin V.M. Electrical Parameters Converters for the Monitoring and Measurement System, M, Energii. 1976, p. 141. 6. Tychino Voltage to frequency converters, M, Energie, 1972, Mass library radio. Top 808. p. 1 1-15, / J L BUT ..fL, - -t ..-. -f- D JO Jf 32 Phage.