RU2549166C1 - Regenerator of single-phase voltage in network - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention suggests regenerator that comprises transformer 1 with secondary winding 2, to which double-pole rectifier 3 is connected, and the winding is connected to terminals 4 of network voltage. The transformer comprises secondary windings 5, and each of them is connected to the respective rectifier 6. Key cascades 7 are connected to rectifiers 6, and each cascade consists of two keys 8 and 9 and key control scheme 10. Inputs of key control scheme 10 for each key cascade 7 are coupled to the respective outputs of reversible counter 11. The first key cascade 7 is coupled to key elements 12 and 13, which together with key elements 14 and 15 create a bridge circuit. Connection point of key elements 14 and 15 is connected to mid point of double-polar rectifier 3. Connection points of key elements 12-14 and 13-15 form output of the regenerator, to which load 17 is coupled through protective unit 16. The regenerator also contains power amplifier 18, comparator 19, comparator 20, resistive divider 21, reference signal generator 22 consisting of generator 23 generating sinusoidal signal, comparator 24, controlled follower 25 and key 26, control circuits 27 and 28 for key elements 13 and 14, inverter 29, control circuits 30 and 31 for key elements 12 and 15.

EFFECT: receiving signal of sinusoidal shape close to ideal sinusoid, providing potential frequency adjustment for output voltage and increasing efficiency factor.

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Description

The invention relates to the field of electrical engineering and can be used in power supply devices for equipment for various purposes, requiring high quality supply voltage of a sinusoidal shape, in particular high-quality audio equipment.

The closest in technical essence and the achieved technical result to the claimed single-phase network voltage regenerator is a single-phase network voltage regenerator (see US Pat. No. 7259705, IPC H03M 1/66, dated 01.02.2006, published on 08.21.2007) comprising a transformer with a secondary winding connected to a bipolar rectifier, a power amplifier, a protection unit, a shaper of a reference sinusoidal signal, the primary winding of the transformer connected to the mains voltage terminals, the first input of the power amplifier is connected the output of the reference signal supply terminals of the power amplifier connected to the output of the bipolar rectifier, the outputs of the regenerator are connected in series via the protection unit with the load.

The well-known single-phase network voltage regenerator provides stabilization of the output voltage and correction of the sinusoidal waveform by summing the voltage of the network with the output voltage of the power amplifier and adjusting the shape of the output voltage to match the reference signal of the sinusoidal shape.

However, it does not provide a sinusoidal signal that is close to an ideal sinusoid, with significant distortion of the network waveform, does not allow you to adjust the frequency of the output voltage and has a low efficiency (efficiency).

This is because the known regenerator has an insufficient range of operating voltages of the power amplifier, as a result of which the output signal of the power amplifier does not sufficiently compensate for fluctuations in the supply voltage in shape and amplitude. If the distortion of the network signal exceeds a certain threshold, then the compensation capabilities of the device are exhausted, and the network distortion falls into the output signal of the regenerator. To expand the compensation capabilities of the device, it is necessary to increase the operating voltage range of the power amplifier. For example, in order to compensate for fluctuations in the mains voltage of ± 20%, the power amplifier must operate in the range of ± 50 V. At an output power of the regenerator of 1 kW, the loss power dissipated by the power amplifier will be about 250 W, i.e. the efficiency of the device is not more than 75%. In the known regenerator, it is not possible to change the frequency of the output signal of the regenerator. The output sinusoidal signal has a frequency equal to the frequency of the mains, i.e. 50 or 60 Hz.

The basis of the invention is the task to improve the single-phase voltage regenerator by introducing new structural elements, new connections between structural elements, a new implementation of structural elements, which will provide a sinusoidal signal close to the ideal sinusoid, will allow you to adjust the frequency of the output voltage and will increase the efficiency (efficiency).

The problem is solved in that in a single-phase voltage regenerator, including a transformer with a secondary winding connected to a bipolar rectifier, a power amplifier, a protection unit, a shaper of a reference sinusoidal signal, the primary winding of the transformer connected to the mains voltage terminals, the first input of the power amplifier is connected to the output of the driver of the reference signal, the power amplifier power outputs are connected to the output of the bipolar rectifier, and the outputs of the regenerator They can be connected via a protection unit to a load. According to the proposed technical solution, the new one is that the regenerator additionally contains 5-7 secondary windings, 5-7 rectifiers, 5-7 key stages, each of which consists of two keys and a key management circuit, two a comparator, a reversible counter, two pairs of key elements equipped with control circuits and connected to a bridge circuit, an inverter, a resistive divider, a shaper of a reference signal additionally includes a controlled repeater, a third comparator and yuch, with each rectifier connected to the corresponding secondary winding, each key stage connected to the output of the corresponding rectifier, the first keys of each key stage connected to each other in series, and the second keys of each key stage connected between the positive output of the corresponding rectifier and the connection point of the first keys, inputs key management circuits of each key stage are connected to the corresponding outputs of the reverse counter, the first key stage is connected to the first pair key elements, the second pair of key elements is connected to the midpoint of the bipolar rectifier, the last key stage is connected to the output of the power amplifier, the output of the power amplifier is also connected to the non-inverting input of the first comparator and the inverting input of the second comparator, the second inputs of the first and second comparators are connected to a resistive divider, moreover, the output of the first comparator is connected to the summing input of the reversible counter, and the output of the second comparator is connected to the subtracting input of the reverse counter, the second input of the power amplifier is connected to the connection point of the first key stage with the first pair of key elements, the output of the comparator of the reference signal generator is connected to the inputs of the control circuits of the first and fourth key elements and the inverter input, the inverter output is connected to the inputs of the control circuits of the second and third key elements moreover, the output voltage of each subsequent rectifier is a multiple of two with respect to the output voltage of each previous rectifier, and the output a regenerator that is connected to the load, is the diagonal of the bridge circuit.

The causal relationship between the set of essential features of the invention and the achieved technical result is as follows.

The introduction of new structural elements and new relationships between structural elements, as well as a new implementation of the structural elements of the inventive regenerator, namely that it:

- additionally contains 5-7 secondary windings,

- additionally contains 5-7 rectifiers,

- additionally contains 5-7 key cascades, each of which consists of two keys and a key management scheme,

- additionally contains two comparators,

- additionally contains a reversible counter,

- additionally contains two pairs of key elements equipped with control circuits and connected to a bridge circuit,

- additionally contains an inverter,

- additionally contains a resistive divider,

- the shaper of the reference signal further includes a controlled repeater, a third comparator and a key,

- in this case, each rectifier is connected to the corresponding secondary winding, each key stage is connected to the output of the corresponding rectifier, the first keys of each key stage are interconnected in series, and the second keys of each key stage are connected between the positive output of the corresponding rectifier and the connection point of the first keys, circuit inputs the key controls of each key stage are connected to the corresponding outputs of the reverse counter, the first key stage is connected to the first pair of keys cell, the second pair of key elements is connected to the midpoint of the bipolar rectifier, the last key stage is connected to the output of the power amplifier, the output of the power amplifier is also connected to the non-inverting input of the first comparator and the inverting input of the second comparator, the second inputs of the first and second comparators are connected to the resistive divider, moreover, the output of the first comparator is connected to the summing input of the reversing counter, and the output of the second comparator is connected to the subtracting input of the reversing counter sensor, the second input of the power amplifier is connected to the connection point of the first key stage with the first pair of key elements, the output of the comparator of the driver of the reference signal is connected to the inputs of the control circuits of the first and fourth key elements and the input of the inverter, the output of the inverter is connected to the inputs of the control circuits of the second and third key elements moreover, the magnitude of the output voltage of each subsequent rectifier is a multiple of two with respect to the magnitude of the output voltage of each previous rectifier, and the output p the generator to which the load is connected is the diagonal of the bridge circuit,

Together with the known features of the technical solution, it provides a sinusoidal signal close to the ideal sinusoid, allows you to adjust the frequency of the output voltage and provides an increase in the efficiency (efficiency).

This is because when the regenerator is connected to the network, the input mains voltage is supplied to the primary winding of the transformer from the mains voltage terminals and then the voltage appears at the output of the bipolar rectifier connected to the secondary winding. At the outputs of 5-7 rectifiers connected to 5-7 secondary windings, voltages appear, and the output voltage of each subsequent rectifier is a multiple of two with respect to the output voltage of each previous rectifier. The output voltages of the rectifiers are switched by 5-7 key stages. When a logical unit arrives at the key management circuit of each of the key stages, the first key of the cascade is closed, and the second key is opened and connects the output of the corresponding rectifier to the input of the bridge circuit. The voltage of the rectifiers, in which the second keys were open, are added up. As a result, at the input of the bridge circuit (the connection point of the first key stage with the first pair of key elements), an equivalent signal of a half-sine wave is formed, which is set by a six-bit binary code. A six-digit key management code is generated at the outputs of the reverse counter. The last key stage is connected to the output of the power amplifier. The midpoint of the bipolar rectifier is connected to the connection point of the second pair of key elements, so the output signal of the power amplifier and the signal generated by switching the key stages are summed between the connection points of the pairs of key elements. Synthesis of a high-precision precision sinusoidal signal at the output of the regenerator is carried out due to the fact that the generator of the reference sinusoidal signal generator generates a precision sinusoidal signal with minimal nonlinear distortion and a stable amplitude at its output. The amplitude and frequency of the output voltage of the generator of the shaper of the reference signal are determined by the operator and correspond to the change in the output voltage of the regenerator in the ranges of 190-230 V and 50-120 Hz. At the output of the comparator of the shaper of the reference signal, rectangular pulses are formed, the edges of which coincide in time with the transitions of the sinusoidal signal through zero. The key driver of the reference signal one half-cycle of the sinusoidal voltage is open, and the next is closed. As a result, the controlled repeater of the shaper of the reference signal one half-cycle is inverting, and the next non-inverting, and a half-sine signal is generated at its output, which is similar in shape to the rectified two-half-voltage. The reference half-sinusoidal signal is fed to the first input of the power amplifier. The feedback signal from the connection point of the first pair of key elements, i.e. a signal equal to the sum of the output voltage of the power amplifier and the voltage across a set of key stages. This sum of voltages is actually the output voltage, which must match in shape with the reference signal. The power amplifier determines the difference of the signals, amplifies it by power and compensates for all deviations of the output voltage from the reference signal. To ensure high compensation accuracy with a relatively small range of the output voltage of the power amplifier, the voltage level at the output of the power amplifier is compared with threshold values by the first and second comparators. The threshold voltage values are set by a resistive divider. If the voltage value at the output of the power amplifier exceeds a predetermined value, or less than a predetermined value, then the first and second comparators form a command to increase, or, accordingly, to reduce the code at the output of the reversible counter. Therefore, the analog power amplifier controls the operation of the key stages in such a way that the difference between the reference signal of a half-sinusoidal shape and the total signal at the output of the key stages at each time point does not exceed the absolute value of the specified value. Then the power amplifier operates in linear mode in the entire range of instantaneous values of the output voltage - from 0 V to 350 V and provides accurate compensation of deviations of the output signal from the equivalent.

The generated half-sinusoidal signal is converted to a sinusoidal one using a bridge circuit on key elements, into the diagonal of which a load is connected through the protection unit. The protection unit disconnects the load from the regenerator output when the load current exceeds the maximum permissible value, for example, during short circuits. The key elements of the bridge circuit are controlled by the corresponding control circuits, which receive signals from the outputs of the comparator of the shaper of the reference signal and inverter. When the first key element of the first pair of key cascades of the bridge circuit and the second key element of the second pair of key cascades of the bridge circuit are open, a positive half-wave of sinusoidal voltage is generated on the load when the second key element of the first pair of key cascades of the bridge circuit and the first key element of the second pair of the key cascades of the bridge are open circuit, a negative half-wave of a sinusoidal voltage is formed on the load.

Thus, in the inventive regenerator, due to the totality of the features, a sinusoidal signal is obtained that is close to an ideal sinusoid, as well as the ability to adjust the frequency of the output voltage and increase the efficiency (efficiency).

The single-phase voltage regenerator of the network is illustrated in the drawing, which shows a functional diagram of the inventive regenerator.

The single-phase network voltage regenerator comprises a transformer 1 with a secondary winding 2, to which a bipolar rectifier 3 is connected. The primary winding of the transformer 1 is connected to the terminals 4 of the mains voltage. The transformer 1 also includes secondary windings 5, each of which is connected to the corresponding rectifier 6. The output no-load voltages of the rectifiers 6 differ from each other by half and are, for example, 200 V, 100 V, 50 V, 25 V, 12 , 5 V and 6 V. The output voltage of the bipolar rectifier 3 should be approximately 1.5 times higher than the output voltage of the smallest (last) rectifier and equal to, for example, ± 10 V. Key stages 7 are connected to rectifiers 6. Each key stage 7 consists of of two keys 8 and 9 and control circuit 10 I am the keys. The first keys 8 of the key stages 7 are connected to each other in series, each second key 9 is connected between the positive terminal of the corresponding rectifier and the connection point of the first keys 8. The inputs of the key management circuits 10 of each key stage 7 are connected to the corresponding outputs of the reversing counter 11. The first key stage 7 is connected with key elements 12 and 13, which together with key elements 14 and 15 form a bridge circuit. The connection point of the key elements 14 and 15 is connected to the midpoint of the bipolar rectifier 3. The connection points of the key elements 12-14 and 13-15 (diagonal of the bridge circuit) are the output of the regenerator, to which the load 17 is connected via the protection unit 16. The last key stage 7 is connected to the output of the power amplifier 18. The output of the power amplifier 18 is also connected with the non-inverting input of the comparator 19 and the inverting input of the comparator 20. The second inputs of the comparators 19 and 20 are connected to the resistive divider 21. The output of the comparator 19 is connected to the summing input of the reversing counter 11, the output of the comparator 20 is connected to the subtracting input of the reversing counter 11 One of the inputs of the power amplifier 18 is connected to the output of the shaper 22 of the reference signal, consisting, for example, of a sinusoidal signal generator 23, a comparator 24, a controlled repeater 25 and a key 26. The second input of the power amplifier 18 is connected to the connection point of the first key stage 7 with the key elements 12 and 13. The power terminals of the power amplifier 18 are connected to the output of the bipolar rectifier 3. The output of the comparator 23 is connected to the inputs of the key elements control circuits 27 and 28 13 and 14 and the input inverter 29. The output of the inverter 29 is connected to the inputs of the control circuits 30 and 31 of the key elements 12 and 15.

The single-phase voltage regenerator operates as follows.

The input mains voltage from the terminals 4 of the mains voltage is supplied to the primary winding of the transformer 1. At the output of the bipolar rectifier 3 connected to the secondary winding 2, a voltage of approximately ± 10 V appears. At the outputs of the rectifiers 6 connected to the secondary windings 5, voltages 200 V, 100 V, 50 V, 25 V, 12.5 V and 6 V. The absolute values of the voltages are not fundamental, it is important that they differ from each other by half. The output voltage of the bipolar rectifier 3 should be approximately 1.5 times greater than the output of the last of the rectifiers 6, for example ± 10 V. The key stages 7 switch the output voltages of the rectifiers 6. When a logical unit arrives at the key management circuit 10 of each of the key of cascades 7, the first key 8 of the cascade is closed, and the second key 9 is opened and connects the output of the corresponding rectifier 6 to the input of the bridge circuit. The voltage of the rectifiers 6, in which the second keys 9 were open, are added up. As a result, at the input of the bridge circuit (the connection point of the first key stage 7 with the first pair of key elements 12 and 13), an equivalent signal of a half-sine wave is formed, which is set by a six-bit binary code. A six-digit key management code 7 is generated at the outputs of the reverse counter 11. The last key stage 7 is connected to the output of the power amplifier 18. Since the midpoint of the bipolar rectifier 3 is connected to the connection point of the second pair of key elements 14 and 15, between the connection points of the pairs of key elements 12-13 and 14-15 the output signal of the power amplifier 18 and the signal generated by the switching of the key stages 7 are summed.

The synthesis of a precision high-power sinusoidal signal at the output of the regenerator is as follows. The sinusoidal signal generator 23 of the reference signal generator 22 generates at its output a precision sinusoidal signal with minimal non-linear distortion and a stable amplitude. The amplitude and frequency of the output voltage of the generator 23 are determined by the operator and correspond to the change in the output voltage of the regenerator in the ranges of 190-230 V and 50-120 Hz. At the output of the comparator 24 of the shaper 22 of the reference signal, rectangular pulses are formed, the edges of which coincide in time with the transitions of the sinusoidal signal through zero. The key 26 of the shaper 22 of the reference signal, one half-cycle of the sinusoidal voltage is open, and the next is closed. As a result, the controlled repeater 25 of the reference signal generator 22 one half-cycle is inverting and the next non-inverting, and a half-sine signal is generated at its output, which is similar in shape to the rectified two-half-voltage. The reference half-sinusoidal signal is supplied to the first input of the power amplifier 18. The feedback signal from the connection point of the first pair of key elements 12 and 13, i.e., a signal equal to the sum of the output voltage of the power amplifier 18 and the voltage generated by the switching of the key stages 7. This sum of the voltages is actually the output voltage, which must coincide in shape with the reference signal. The power amplifier 18 determines the difference of the signals, amplifies it in power and compensates for all deviations of the output voltage from the reference signal. To ensure high compensation accuracy with a relatively small range of the output voltage of the power amplifier 18, the voltage level at the output of the power amplifier 18 is compared with threshold values by comparators 19 and 20. The threshold voltage values of ± 10 V are set by resistive divider 21. If the voltage value at the output of the amplifier 18 of power reaches a level of plus 9 V, or minus 9 V, then the comparators 19 and 20 form a command to increase, or, respectively, to reduce the code at the output of the reverse counter 11 per unit nitsu. Therefore, the analog power amplifier 18 controls the operation of the key stages 7 in such a way that the difference between the reference signal of a half-sine wave and the total signal at the output of the key stages 7 at each time point does not exceed the absolute value of 9 V. Then, the power amplifier 18 operates in a linear mode during the entire range of instantaneous values of the output voltage - from 0 V to 350 V and provides accurate compensation for deviations of the output signal from the equivalent. The generated half-sinusoidal signal is converted into a sinusoidal one using a bridge circuit on the key elements 12, 13, 14 and 15, into the diagonal of which a load 17 is connected through the protection unit 16. The protection unit 16 disconnects the load 17 from the regenerator output when the load current exceeds the maximum permissible value, e.g. for short circuits. The key elements 12-15 of the bridge circuit are controlled by the corresponding control circuits 27, 28 and 30, 31, which receive signals from the outputs of the comparator 24 and the inverter 29. When the key stages 12 and 15 are open, a positive half-wave of a sinusoidal voltage is generated at the load, when the key cascades 13 and 14 are negative.

In the regenerator, selected as a prototype, the output signal of the power amplifier compensates for fluctuations in the mains voltage in shape and amplitude. If the distortion of the network signal exceeds a certain threshold, then the compensation capabilities of the device are exhausted, and the network distortion falls into the output signal of the regenerator. To expand the compensation capabilities of the device, it is necessary to increase the operating voltage range of the power amplifier. For example, in order to compensate for mains voltage fluctuations of ± 20%, the power amplifier must operate in the range of ± 50 V. At a regenerator output power of 1 kW, the loss power dissipated by the power amplifier will be up to 250 W, i.e. the efficiency of the regenerator is not more than 75%. In the proposed regenerator, the power amplifier controls the value of the total signal at the output of the key stages so that to fully compensate for deviations from the reference signal, a range of the output signal of the power amplifier ± 10 V is sufficient. The power loss of the amplifier with an output power of the regenerator of 1 kW will be no more than 50 W . Given the power losses in the key stages and in the transformer, the efficiency of the regenerator as a whole exceeds 90%, which is much higher than the efficiency of the regenerator, which is selected as a prototype.

In the regenerator selected as a prototype, the frequency of the output signal of the regenerator cannot be changed. The output sinusoidal signal has a frequency equal to the frequency of the mains, i.e. 50 or 60 Hz. In the proposed regenerator, the output voltage can have any frequency equal to the frequency of the reference signal, for example, be regulated in the range of 50-120 Hz. This feature, which the regenerator known from the prototype does not provide, is an important technical advantage, since it improves the quality of work, for example, of high-quality audio equipment for which the regenerator is intended to be powered.

As can be seen from the foregoing, in the inventive single-phase network voltage regenerator, a sinusoidal signal is obtained that is close to an ideal sinusoid, it is possible to adjust the frequency of the output voltage and provides an increase in the efficiency (efficiency).

The inventive single-phase voltage regenerator can be manufactured using known equipment and using known materials and means, which confirms its industrial suitability.

Claims (1)

A single-phase network voltage regenerator including a transformer with a secondary winding connected to a bipolar rectifier, a power amplifier, a protection unit, a reference sinusoidal signal shaper, the transformer primary winding connected to the mains voltage terminals, the first input of the power amplifier connected to the output of the reference signal shaper, power leads the power amplifier is connected to the output of a bipolar rectifier, and the outputs of the regenerator are connected in series through the protection unit to the load oh, characterized in that the regenerator additionally contains 5-7 secondary windings of the transformer, 5-7 rectifiers, 5-7 key stages, each of which consists of two keys and a key management circuit, two comparators, a reversible counter, two pairs of key elements, equipped with control circuits and connected to the bridge circuit, the inverter, resistive divider, the driver of the reference signal further includes a controlled repeater, a third comparator and a key, with each rectifier connected to a corresponding secondary with a coil, each key stage is connected to the output of the corresponding rectifier, the first keys of each key stage are interconnected in series, and the second keys of each key stage are connected between the positive output of the corresponding rectifier and the connection point of the first keys, the inputs of the key management circuits of each key stage are connected to the corresponding outputs a reverse counter, the first key cascade is connected to the first pair of key elements, the second pair of key elements is connected to the middle the second point of the bipolar rectifier, the last key stage is connected to the output of the power amplifier, the output of the power amplifier is also connected to the non-inverting input of the first comparator and the inverting input of the second comparator, the second inputs of the first and second comparators are connected to the resistive divider, and the output of the first comparator is connected to the summing input of the reverse counter, and the output of the second comparator is connected to the subtracting input of the reverse counter, the second input of the power amplifier is connected to the connection point of the first key stage with the first pair of key elements, the output of the comparator of the driver of the reference signal is connected to the inputs of the control circuits of the first and fourth key elements and the input of the inverter, the output of the inverter is connected to the inputs of the control circuits of the second and third key elements, and the output voltage of each subsequent rectifier is a multiple of two in relation to the value of the output voltage of each previous rectifier, and the output of the regenerator to which the load is connected is the diagonal of the bridge marketing scheme.