RU2361264C2 - Method of ac voltage control - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention relates to electronics and automatics, namely, to conversion of a.c. energy at inputs into a.c. energy at outputs to change voltage avoiding intermediate conversion into direct current. Method of a.c. voltage control provides for converting voltage into bipolar pulses sequence having significantly higher frequency relative to input voltage input. The pulse time defines the value of voltage controlled. The said conversion is realised by antiphase opening and closing of two switches. The voltage is supplied to parallel relay input (5.2) and input relay input (4.2) with its other input (4.3) being coupled with a choke input. Input (4.1) is coupled with output relay input (6.1) with its other input (6.2) being connected to the common circuit. Input (6.3) is coupled with sequential switch output, while its input is coupled with the choke output and parallel switch input. The parallel switch output is connected with parallel relay input (5.3). Parallel switch input (5.1) is coupled with the common circuit. The load is connected to output relay input (6.1). In order to increase voltage, input relay input (4.3) is switched to input (4.2), while input (5.3) is coupled with parallel relay input (5.1) and input (6.3) with output relay input (6.1). On the contrary, in order to decrease voltage, input (4.3) is switch to input relay input (4.1), input (5.3) is switched to parallel relay input (5.2) and input (6.3) with output relay input (6.2).

EFFECT: reduced weight and dimensions of devices used during ac voltage control and wide application of the said process; improved reliability and reduced cost due to application of other devices and other sequence of operations while maintaining continuous current at load input.

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Description

The invention relates to the field of electronics and automation, and in particular to processes for converting AC energy at the input to AC energy at the output to change the voltage value without intermediate conversion to DC using devices made on semiconductor elements with control electrodes and equipped with elements serving for closing and opening contacts.

Regulation of the magnitude of AC voltage is required in power supply, automation systems, AC drives and many other electronic devices. Such regulation is often carried out using magnetic amplifiers, multi-winding transformers with thyristor switching windings, various thyristor circuits that change the actual voltage value. These methods, as a rule, involve the use of devices that have a relatively large mass, dimensions and do not provide the required voltage regulation limits or distort the shape of a sinusoidal voltage.

An important parameter that determines the efficiency of the process of regulating the magnitude of the AC voltage is the provision of energy recovery with the reactive nature of the load. Energy recovery is possible while providing galvanic communication between the source and consumer of electricity. However, the use of transformer circuits of devices for regulating the magnitude of the AC voltage does not provide recovery.

To regulate the magnitude of the AC voltage at the load, methods are also used that involve the use of autotransformer devices controlled by the engine. The use of autotransformer devices provides energy recovery with a complex nature of the load, however, these devices have a relatively large mass and dimensions, leading to an increase in the cost of the regulation process and low speed.

There is a method of smoothly regulating AC voltage, presented in the description of the invention to the patent of the Russian Federation No. 2266608 (IPC: Н02М 03/22, Н02М 07/527, G05F 01/56; publ. 20.12.2005 in bull. No. 35).

In accordance with this method, based on the conversion of AC voltage to a sequence of bipolar pulses of a significantly higher frequency, the duration of which determines the magnitude of the regulated voltage, the received pulses are fed through a high-frequency transformer that sets the regulation limits to a synchronous rectifier, the phase change of which switches the phase changes the adjustable voltage of the initial frequency obtained at the output of the smoothing filter, to the opposite.

The circuit of the device with which the described method for regulating the AC voltage can be implemented includes an inverter consisting of four keys, a high-frequency transformer, a synchronous rectifier and a smoothing filter.

As you can see, the implementation of the above method involves the use of a large number of elements that have a relatively large mass and dimensions, in particular a high-frequency transformer. This method of regulating AC voltage is relatively expensive and not reliable enough, due to the presence of six semiconductor switches. In addition, the presence of a transformer does not provide the possibility of recovery, which significantly reduces the effectiveness of the regulation method.

A known method of increasing the magnitude of the AC voltage at the load (A. Korshunov. "Pulse AC voltage converters", "Power Electronics", No. 1, 2006, p. 54-61), involving only the inductor, parallel key and serial key in lack of transformer devices.

In this method, the input AC voltage is fed to the input of the inductor, the output of which is connected to the inputs of the parallel and serial keys. The serial key output is connected to the load, and the parallel key output is connected to a common wire.

The regulation of the output voltage is carried out by changing the duration of the parallel key in the closed position, which is determined by the expression

γ = τ / T = τ × f, 0 <γ <1;

where τ is the time spent by the parallel key in the closed position during the period T = 1 / f conversion of the pulses of the input AC voltage into a pulse voltage;

f is the switching frequency of the parallel key.

The average value of the output voltage U _o can be determined by the expression

U _o = U _in / (1-γ);

where U _I - the value of the input voltage of the alternating current.

The described method of increasing the magnitude of the AC voltage at the load provides continuous current at the input, involves the use of a relatively small in size and mass of the inductor. In this case, the output voltage coincides in phase with the input voltage. In this case, energy recovery is provided by the ratio of the on and off states of the parallel (duration τ) and serial (duration T - τ) keys or, in other words, antiphase key management.

At the same time, the described method provides for discontinuous current output and does not allow to reduce the value of the output voltage of the alternating current.

The same source contains a description of the method of lowering the magnitude of the AC voltage without using transformer devices, which also involves the use of a choke, a parallel key and a serial key.

In this method, the input AC voltage is applied to the input of the serial key, the output of which is connected to the input of the inductor and the input of the parallel key. The output of the parallel key is connected to a common wire, and a load is connected to the output of the inductor.

The regulation of the value of the output voltage in this method, as in the previous case, is carried out by changing the length of the serial key in the closed position, which is determined by the expression

γ = τ / T = τ × f, 0 <γ <1;

where τ is the time spent by the parallel key in the closed position during the period T = 1 / f conversion of the pulses of the input AC voltage into a pulse voltage;

f is the switching frequency of the parallel key,

In this case, the average value of the output voltage U _o is determined by the expression

U _o = γ × U _in ;

where U _I - the value of the input voltage of the alternating current.

The described method of lowering the magnitude of the AC voltage at the load provides continuous output current, involves the use of a relatively small in size and mass of the inductor. In this case, the output voltage coincides in phase with the input voltage. In this case, energy recovery is provided by the ratio of the on and off states of the parallel (duration τ) and serial (duration T - τ) keys or, in other words, antiphase key management.

At the same time, the described method provides for the discontinuous current at the input and does not allow to increase the value of the output voltage of the alternating current.

The issue of reactive energy recovery in both described methods of regulating the magnitude of the alternating current voltage under non-linear load is solved by using four square alternating current keys (for example, a diode bridge with a power transistor (IGBT) in the diagonal for which the input and output are only conditional) . If the load is reactive in nature, then due to the phase shift between the load current and voltage, a reversible reactive current occurs, which flows back to the network, in this case the parallel switch acts as a modulator, and the serial switch acts as a synchronous rectifier.

The use of both described methods of regulating the magnitude of the AC voltage in relation to one load by parallel switching on the inputs of the two above-described connection circuits of the elements, one of which is used to increase the value of the output voltage of the alternating current, and the second to reduce the value of the output voltage of alternating current, by alternately switching the load through a relay with a circuit connecting elements used to increase or decrease the magnitude of the AC voltage, leads to a break at the load circuit at the time of switching. In addition, in this case, the mass and dimensions of the totality of the elements used in the process are doubled.

A known method of regulating the magnitude of the AC voltage at the load described in the already mentioned source (A. Korshunov. "Pulse AC voltage converters", "Power Electronics", No. 1, 2006, p. 54-61), involving only the inductor and two parallel keys in the absence of transformer devices. This method allows you to both increase and decrease the magnitude of the AC voltage on a single load.

In this method, the input AC voltage is supplied to the input of the first serial key, the output of which is connected to the input of a parallel inductor and the input of the second serial key. The output of the second serial key is connected to the load, and the output of the parallel inductor is connected to a common wire.

The regulation of the output voltage of the alternating current in this method is carried out by changing the length of stay of the first serial key in the closed position, which is determined by the expression

γ = τ / T = τ × f, 0 <γ <1;

where τ is the time spent by the first serial key in the closed position during the period T = 1 / f conversion of the pulses of the input AC voltage to a pulse voltage;

f is the switching frequency of the first serial key.

In this case, the average value of the output voltage U _o is determined by the expression

U _oi = -U _ox × γ / (1-γ);

where U _I - the value of the input voltage of the alternating current.

This method of regulating the magnitude of the AC voltage allows both raising and lowering the voltage at one load, provides recovery and involves the use of a small number of elements, and also does not require the use of transformer devices having significant weight and dimensions. This method is the closest in technical essence to the claimed method of regulating the magnitude of the AC voltage and is selected as the closest analogue.

At the same time, the described method for regulating the magnitude of the AC voltage provides for the presence of intermittent current at the input and output of the connection circuit of the elements used in this process. Given that the output voltage is in antiphase with the input voltage, it becomes necessary to use high-voltage power switches, taking into account the voltage on them, which is two times higher than the voltage in the last two control methods described above, which leads to an increase in the size, weight and cost of these switches , and also reduces the reliability of the regulatory process. In addition, the described method involves the use of a choke, which accumulates energy in the entire range of power transmitted to the load. This leads to an increase in the mass, dimensions and cost of this element, and also reduces the reliability of the regulatory process.

Thus, the described disadvantages of the closest analogue lead to an increase in the mass and dimensions of the aggregate of elements used in the process and, accordingly, limit the scope of the described method, and also lead to an increase in cost and a decrease in the reliability of the process of regulating the magnitude of the AC voltage.

Given the foregoing, the signs of the closest analogue that coincide with the essential features of the proposed invention are: the implementation of the conversion of voltage into a sequence of bipolar pulses of a significantly higher frequency relative to the frequency of the input AC voltage, the duration of which determines the magnitude of the regulated voltage; the implementation of this conversion by antiphase closure and opening of two keys.

The basis of the invention is the task of reducing the mass and dimensions of the aggregate of devices used in the process of regulating the magnitude of AC voltage, which will expand the scope of such a process, as well as increase its reliability and reduce cost by using other devices and a different sequence of operations on them, while ensuring continuous current at the input of the load.

The problem is solved due to the fact that in the method of regulating the magnitude of the AC voltage, in which the voltage is converted into a sequence of bipolar pulses of a significantly higher frequency relative to the frequency of the input AC voltage, the duration of which determines the magnitude of the regulated voltage, and this conversion is carried out by antiphase closing and opening of two keys, in accordance with the invention, the AC voltage is applied to input 5.2 parallel relay and input 4.2 of the input relay, the input 4.3 of which is connected to the input of the inductor, and the input 4.1 is connected to the input 6.1 of the output relay, the input of 6.2 of which is connected to the common circuit, and the input 6.3 is connected to the output of the serial key, the input of which is connected to the output of the inductor and an input of a parallel switch, the output of which is connected to the input 5.3 of the parallel relay, the input 5.1 of which is connected to a common circuit, and the load is connected to the input 6.1 of the output relay, while, to increase the value of the AC voltage, the input 4.3 is switched to the input 4.2 input one relay, input 5.3 with input 5.1 of the parallel relay and input 6.3 with input 6.1 of the output relay, and to lower the AC voltage, switch input 4.3 with input 4.1 of the input relay, input 5.3 with input 5.2 of the parallel relay and input 6.3 with input 6.2 of the output relay .

It is these signs that are necessary and sufficient to solve the task.

As you can see, the inventive method involves the use of a minimum number of elements having a minimum size, weight and cost, namely one inductor, two semiconductor switches and three relays, the communications of which also provide minimum dimensions, weight and cost while ensuring sufficient reliability of the regulation process as a whole . In contrast to the closest analogue of the connection of the elements used in the claimed method, as well as the sequence of operations on them, you can use the throttle and keys, which have several times smaller weight, dimensions and cost, and also have significantly greater reliability. So, ensuring that the input and output voltages are in phase in the claimed method causes a two-fold decrease in the voltage on the switches, which allows the use of switches with much smaller dimensions and weight. In addition, the modes of voltage addition and voltage subtraction, carried out in the proposed method, cause a reduction of at least two times the amount of power accumulated in the inductor, which allows the use of an inductor with significantly smaller dimensions and weight. Thus, the combination of two keys, a throttle and three relays used in the present method, has a lower mass and dimensions compared to the combination of elements used in the closest analogue. Moreover, the inventive method ensures the continuity of the current at the input of the load.

When AC voltage is applied to input 5.2 of the parallel relay and input 4.2 of the input relay, input 4.3 of which is connected to the input of the inductor, and input 4.1 is connected to input 6.1 of the output relay, input 6.2 of which is connected to the common circuit, and input 6.3 is connected to the output of the serial a key whose input is connected to the output of the throttle and the input of the parallel key, the output of which is connected to the input 5.3 of the parallel relay, whose input 5.1 is connected to the common circuit, and the load is connected to the input 6.1 of the output relay, it is possible to increase and lower values of AC voltage using the same elements. At the same time, the current at the input and output is ensured, the voltage at the switches is halved, the amount of power accumulated in the inductor is reduced, which allows to minimize the mass and dimensions of the set of devices used in the process of regulating the magnitude of the AC voltage, increase its reliability and reduce the cost .

By switching input 4.3 with input 4.2 of the input relay, input 5.3 with input 5.1 of the parallel relay and input 6.3 with input 6.1 of the output relay, and also by switching input 4.3 with input 4.1 of the input relay, input 5.3 with input 5.2 of the parallel relay and input 6.3 with input 6.2 of the output relay, it is possible to operate and switch modes of increasing and decreasing the magnitude of the AC voltage, respectively, using only one inductor and two keys, which also allows you to minimize the weight and dimensions of the combination used in otsesse adjusting the alternating current voltage devices, improve reliability and reduce cost. At the same time, current continuity is ensured at input 5.2 of the parallel relay and input 6.1 of the output relay.

The essence of the invention is illustrated by drawings, where:

figure 1 is an electrical functional diagram of a device that implements a method of regulating the magnitude of the voltage of alternating current;

figure 2 is an electrical functional diagram of an AC voltage stabilizer that implements a method of regulating the magnitude of the AC voltage.

A device that implements a method of regulating the magnitude of the AC voltage (Fig. 1) consists of a serial key 1, a parallel key 2, an inductor 3, an input relay 4, a parallel relay 5 and an output relay 6.

AC input voltage is applied to input 5.2 of parallel relay 5 and to input 4.2 of input relay 4, input 4.3 of which is connected to input of inductor 3, and input 4.1 is connected to input 6.1 of output relay 6, input 6.2 of which is connected to a common circuit, and input 6.3 connected to the output of the serial key 1, the input of which is connected to the output of the inductor 3 and the input of the parallel key 2, the output of which is connected to the input 5.3 of the parallel relay 5, the input 5.1 of which is connected to a common circuit. The load is connected to the input 6.1 of the output relay 6.

The input AC voltage using a parallel switch 2 is converted into a sequence of pulse-width modulated bipolar pulses. The duration of the pulse-width modulated bipolar pulses determines the magnitude of the voltage at the load. Choke 3 accumulates charge energy. Using the serial key 1, synchronous rectification of the discharge current energy stored in the inductor 3 is performed. In this case, the parallel key 2 and the serial key 1 are closed and opened in antiphase.

The operation of keys 1 and 2 in antiphase ensures the recovery of reactive energy under non-linear load. If the load is reactive, then due to the phase shift between the load current and the voltage, a reversible reactive current occurs, which flows back to the network, in this case, the parallel switch 2 works as a modulator, and the serial switch 1 works as a synchronous rectifier.

The mode of increasing the magnitude of the AC voltage is provided by switching the input 4.3 with the input 4.2 of the input relay 4, the input 5.3 with the input 5.1 of the parallel relay 5 and the input 6.3 with the input 6.1 of the output relay 6.

The mode of lowering the AC voltage is provided by switching input 4.3 with input 4.1 of input relay 4, input 5.3 with input 5.2 of parallel relay 5 and input 6.3 with input 6.2 of output relay 6.

At the same time, by phase locking and opening the parallel switch 2 and the serial switch 1, the voltage is converted to a sequence of bipolar pulses of a significantly higher frequency relative to the frequency of the input AC voltage, the duration of which determines the magnitude of the regulated voltage.

One possible implementation of the proposed method for regulating the magnitude of the AC voltage is a single-phase AC voltage stabilizer (Fig.2), designed to provide power to various consumers in conditions of large in value and duration of voltage deviations in the 220 V network with a frequency of 50 Hz with a range of working input voltages from 120 to 380 V, providing a efficiency of at least 93% with an input voltage in the range from 160 to 240 V.

The AC voltage stabilizer (Fig. 2) consists of a serial switch 1, a parallel switch 2, an inductor 3, an input relay 4, a parallel relay 5, an output relay 6, an input low-pass filter 7, an output low-pass filter 8 and includes a control circuit 9 connected to the control inputs of keys and relays.

The input filter of the low frequency 7 of the stabilizer is connected to an AC voltage source, and a load, such as an electric motor, is connected to the output of the output filter of a low frequency 8 of the stabilizer. Using the parallel switch 2, the input AC voltage is converted into a sequence of pulse-width modulated bipolar pulses. The duration of the pulse-width modulated bipolar pulses determines the magnitude of the voltage at the load. Choke 3 accumulates charge energy. Using the serial key 1, the synchronous rectification of the discharge current energy stored in the inductor is carried out. In this case, keys 1 and 2 work in antiphase. Using the control circuit 9 provide antiphase switching keys 1 and 2 with a frequency much higher than the frequency of the input AC voltage. The input low-pass filter 7 and the output low-pass filter 8 suppress the high-frequency components of the modulated voltage in the input voltage source circuit and in the load.

The operation of keys 1 and 2 in antiphase ensures the recovery of reactive energy under non-linear load. If the load is reactive, then due to the phase shift between the load current and the voltage, a reversible reactive current occurs, which flows back to the network, in this case, the parallel switch 2 works as a modulator, and the serial switch 1 works as a synchronous rectifier.

If an AC voltage of equal or less than 220 V is supplied to the input of the stabilizer, the stabilizer operates in a voltage boost mode, which is achieved by switching input 4.3 with input 4.2 of input relay 4, input 5.3 with input 5.1 of parallel relay 5 and input 6.3 with input 6.1 of output relay 6. In this case, antiphase control pulse-width modulated pulses are supplied to the parallel switch 2 and the serial switch 1, and the switch-on time of switch 2 is longer than the switch-on time of switch 1.

If an AC voltage of greater than 220 V is supplied to the input of the stabilizer, the stabilizer operates in a voltage reduction mode, which is achieved by switching input 4.3 with input 4.1 of input relay 4, input 5.3 with input 5.2 of parallel relay 5, and input 6.3 with input 6.2 of output relay 6.

The above-described method of regulating the magnitude of the AC voltage, in comparison with existing analogues, allows you to minimize the weight and dimensions of the aggregate of devices used in the process of regulating the magnitude of the AC voltage, increase its reliability and reduce the cost.

Claims (1)

The method of regulating the magnitude of the AC voltage, in which the voltage is converted to a sequence of bipolar pulses of a significantly higher frequency relative to the frequency of the input AC voltage, the duration of which determines the magnitude of the regulated voltage, and this conversion is carried out by out-of-phase closing and opening of two keys, characterized in that the AC voltage is applied to the input (5.2) of the parallel relay and to the input (4.2) of the input relay, input (4.3) which is connected to the input of the inductor, and the input (4.1) is connected to the input (6.1) of the output relay, the input (6.2) of which is connected to the common circuit, and the input (6.3) is connected to the output of the serial key, the input of which is connected to the output of the inductor and the parallel input a key whose output is connected to the input (5.3) of the parallel relay, the input (5.1) of which is connected to a common circuit, and the load is connected to the input (6.1) of the output relay, and to increase the value of the AC voltage, switch input (4.3) with the input ( 4.2) input relay, input (5.3) with input (5.1) parallel the relay and input (6.3) with the input (6.1) of the output relay, and to lower the AC voltage, switch input (4.3) with the input (4.1) of the input relay, input (5.3) with the input (5.2) of the parallel relay and input (6.3 ) with the input (6.2) of the output relay.

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