RU2582654C1 - Triphase-triphase frequency converter - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention relates to electrical engineering. Frequency converter comprises input terminals of A, B, C for connection of supply mains, output terminals for connection of three-phase load, three equally made three-phase transformer (TT), each of which comprises first and second input and output three-phase windings (TW). Initial leads of phase windings of first input TW and ends of phase windings of second input TW are connected to corresponding input terminals A, B and C, and other leads of each of input TW are connected to, related to said winding, a switching element in form of a three-phase diode bridge with electronic switch in DC circuit. Phase windings of input TW that one of transformer is connected in series to input terminals A, B, C, and phase windings of input TW of two other TT are connected in series to input terminals B, C, A and C, A, B. Similar phase windings of output TW of said three-phase transformers are connected in series in three branches, which are combined in star circuit to make three-phase output.

EFFECT: technical result is possibility of increasing efficiency of frequency conversion, expansion of functional capabilities and field of use of converter.

1 cl, 4 dwg

Description

The invention relates to electrical engineering and can be used in reversible and high-frequency electric drives, in stand-alone power supplies driven by a turbogenerator or diesel generator to provide consumers with electricity with the required frequency and voltage, and in units of guaranteed (uninterrupted) power.

The main trends in improving the energy performance of three-phase-three-phase frequency converters are associated with improving the shape of the output voltage curve (improving the harmonic composition of the output voltage), including when regulating it. This requirement is also relevant for the class of direct frequency converters (NFC), in which the output voltage is formed by modulating directly from the segments of the sinusoid phases of the supply network.

The most effective way to convert the frequencies in these low-frequency drives are technical solutions in which the phases of the network are connected to the phases of the load cyclically at regular intervals. The conversion process is carried out either by direct modulation, or by modulation and demodulation. Known transformerless frequency converters with a three-phase output, providing the possibility of synthesizing sinusoidal output voltage curves, are given in the book by Juji L., Pelly B. Power semiconductor frequency converters: Theory, characteristics, application. Per. from English - M .: Energoatomizdat, 1983.P. 312-316. However, the known transformerless converters do not provide the possibility of obtaining at the output of the converter a voltage equal to or higher than the voltage at its input. Their disadvantages can also be attributed to a significant deterioration in the harmonic composition of the voltage at the output of the NPC during voltage regulation.

A known converter of an m-phase voltage system of one frequency to an n-phase voltage system of another frequency (SU 515222, H02M 5/257, H05P 7/62, 1976). The known converter comprises an m-phase transformer with two secondary m-phase windings, two m target keys in the form of two uncontrolled m-phase valve bridges with fully controlled switches on the DC side, the inputs of these bridges being connected to the opposite ends of the two secondary windings of the transformer, and the other ends of these windings, belonging to the same phase, are interconnected, as well as mn-phase controlled valve bridges, the inputs of each of the nm-phase controlled bridges are connected to the indicated points union of the secondary windings of the transformer.

However, the known frequency converter does not provide the ability to obtain a load voltage with a frequency equal to or greater than the frequency of the supply voltage.

To obtain the required values of the frequency (higher than the frequency of the supply network) and the output voltage at the load equal to or higher than the voltage of the supply network, the NPC uses, as a rule, a structure containing a modulator, a matching transformer and a demodulator.

A known frequency converter, which in addition to a three-phase matching transformer contains input circuits in the form of a three-phase group of primary windings of this transformer and output circuits that perform the functions of voltage and frequency regulation, containing three equally executed groups of three-phase secondary windings and three switching elements, each in the form of a three-phase diode bridge connected by AC clamps to the same phase terminals of one of the indicated groups of windings, and by DC clamps to power terminals odes of a transistor switch connected in the conducting direction, while other terminals of the same name of each three secondary windings of different phases and groups are connected to one of the terminals of a three-phase load (Thyristor frequency converters in an electric drive. Ed. PC Sarbatova. M .: Energy, 1980.S. 280).

A disadvantage of the known frequency converter is the low conversion efficiency due to the fact that the output voltage contains almost the entire spectrum of harmonic components.

Known single-phase bridge frequency converter according to patent RU 104401 U1 (H02P 27/18, 2011). The known frequency converter comprises a terminal device including the first and second windings, and the terminal device is configured to be connected to the electrical supply network through the first and second bridge rectification circuits containing electronic keys. The bridge rectification schemes are each made in the form of a single-phase uncontrolled bridge, in the diagonal of which an electronic key is included in the conductive direction. Moreover, the first input of each single-phase uncontrolled bridge is designed to connect to the first input of the electrical supply network. The second input of one single-phase uncontrolled bridge is connected to the end of the first winding, and the second input of another single-phase uncontrolled bridge is connected to the beginning of the second winding. At the same time, the beginning of the first and the end of the second windings are designed to be connected to the second input of the electric supply network.

The well-known single-phase bridge frequency converter can be used as the basis for creating a three-phase frequency converter, however, in this case, the circuit diagram of a three-phase converter will contain nine single-phase transformers and eighteen controlled keys, which complicates the frequency converter and reduces its reliability and efficiency.

A known frequency converter according to patent RU 2256284 C1 (H02M 5/297, 2005). The known frequency converter contains a control unit and groups of parallel-connected pairs of series-connected keys, as well as a phasing unit and a filtering unit connected to the inputs of the frequency converter, and transformers in an amount equal to the number of phases of the input voltage. In this case, some outputs of the control unit are connected through the phasing unit to the control inputs of some keys, other outputs of the control unit are sequentially through the filtering unit and the phasing unit are connected to the control inputs of other keys. The primary windings of the transformers are connected to the inputs of the frequency converter through one corresponding group of keys, assembled by bridge voltage conversion circuits and combined into a star or polygon. The secondary windings of different transformers are connected in series. The extreme terminals of these groups of windings are connected to the inputs of the frequency converter through other corresponding groups of keys, assembled by bridge voltage conversion circuits and combined into a star.

A disadvantage of the known solution is the need to convert an alternating three-phase voltage at the input of a frequency converter into alternating voltage of increased frequency at the terminals of the groups of secondary windings of transformers, which is then converted into a three-phase width-modulated alternating voltage at the outputs of the frequency converter. To implement this conversion, 24 managed keys are used. The complex conversion process, the large number of managed keys and the complexity of the control circuit reduce the reliability and efficiency of the device.

The closest in combination of essential features with the claimed invention is a three-phase-three-phase frequency converter described in the description of the invention according to patent RU 2239274 C1 (H02M 5/297, 2004). The known frequency converter contains a three-phase supply network, a transformer unit with three-phase input and output windings, and switching elements made in the form of three-phase diode bridges with electronic switches in the DC circuit. To obtain a three-phase voltage increased frequency in the primary windings of the transformer, the input converter circuits are made similar to the output circuits, namely, using the same three-phase three-phase groups of primary windings and three switching elements, each in the form of a three-phase diode bridge with AC clamps connected to the primary terminals of the same name windings of one of the three-phase groups, and with DC clamps - to the power terminals of the transistor switch included in the conductive direction. In this case, the other conclusions of each three primary windings of phases and groups are connected to one of the phases of the supply network.

The disadvantages of the known solutions include the need for modulation and demodulation processes when converting alternating current of one frequency at the input of a frequency converter into three-phase alternating current of another frequency at its output. In addition, the output voltage contains the entire spectrum of higher harmonic components. The noted shortcomings make the conversion process inefficient, limit the functionality and scope of the frequency converter.

The present invention is the creation of a three-phase-three-phase frequency converter, providing increased efficiency of the frequency conversion process, expanding the functionality and scope of the frequency converter.

This problem is solved by the fact that a three-phase-three-phase frequency converter is proposed, containing input terminals A, B, C for connecting the mains, output terminals for connecting a three-phase load, three equally made three-phase transformers, each of which includes the first and second input and output three-phase windings. The initial terminals of the phase windings of the first input three-phase winding and the ends of the phase windings of the second input three-phase winding are connected to the corresponding input terminals A, B and C, and the other terminals of each of the input three-phase windings are connected to the corresponding switching element in the form of a three-phase diode bridge with an electronic key in a direct current circuit. The phase windings of the input three-phase windings of one three-phase transformer are connected in series to the input terminals A, B, C, and the phase windings of the input three-phase windings of two other three-phase transformers are connected in series to the input terminals B, C, A and C, A, B. Phase windings of the same name the output three-phase windings of said three-phase transformers are connected in series in three branches, which are combined in a star circuit and form a three-phase output.

The technical result of the use of the invention is that it provides the ability to create a three-phase-three-phase frequency converter, which allows to increase the efficiency of the frequency conversion process and to expand the operational capabilities and scope of the converter.

In FIG. 1 presents a diagram of the inventive frequency converter; in FIG. 2 is a diagram of voltage generation at the output of a frequency converter; in FIG. 3 - diagrams of the voltage formation at the output of the frequency converter when regulating the output voltage; in FIG. 4 is the same. In the diagrams: U _A1 is the voltage generated on the phase windings 23, 26 of the input windings 14, 15 of the three-phase transformer 2; U _B1 is the voltage generated on the phase windings 32, 35 of the input windings 17, 18 of the three-phase transformer 3; U _C1 is the voltage generated on the phase windings 41, 44 of the input windings 20, 21 of the three-phase transformer 4; U _{a (62)} is the total phase voltage generated on the series-connected phase windings 29, 38, 47 of the output windings 16, 19, 22 of three-phase transformers 2-4, applied to the load 62; ω is the circular frequency; t is the time; 56-61 - intervals of inclusion of the corresponding electronic keys.

The frequency converter contains input terminals A, B, C for connecting the supply network 1, output terminals a, b, c for connecting a three-phase load, three equally made three-phase transformers 2-4 with magnetic circuits 5-7, 8-10 and 11-13, respectively . Input three-phase windings 14, 15 and output three-phase winding 16 are located on three-phase transformer 2. Input three-phase windings 17, 18 and output three-phase winding 19 are located on three-phase transformer 3. Input three-phase windings 20, 21 and output three-phase winding 22 are located on three-phase transformer 4 The mentioned input and output three-phase windings include phase windings 23-49. The initial terminals of the phase windings 23-25, 32-34 and 41-43, as well as the ends of the phase windings 26-28, 35-37 and 44-46 are connected to the corresponding input terminals A, B and C. In this case, the phase windings 23, 26 , 34, 37 and 42, 45 are connected to the input terminal A. Phase windings 24, 27, 32, 35 and 43, 46 are connected to the input terminal B. Phase windings 25, 28, 33, 36 and 41, 44 are connected to the input terminal C. Other outputs of the mentioned phase windings of the three-phase input windings 14, 17 and 20 are connected to the variable inputs of the corresponding switching elements 50-55, each of which is made in the form of a three-phase diode bridge with e ics key (56-61) in the DC circuit. Magnetic cores 5, 8, 11 and phase windings 23, 26, 32,35, 41, 44 belong to phase A, magnetic cores 6, 9, 12 and phase windings 24, 27, 33, 36, 42, 45 belong to phase B, magnetic circuits 7,10,13 and phase windings 25,28, 34, 37,43,46 - to phase C.

Phase windings 16, 19, 22, phase windings 29, 39, 48 and phase windings 31, 40 49 (i.e. the same windings) of the output three-phase windings 16, 19 and 22 of three-phase transformers 2-4 are connected in series in three branches, which combined in a star circuit and form a three-phase output.

Three-phase-three-phase frequency converter operates as follows.

The conversion of three-phase alternating current in a frequency converter is based on the principle of three-band modulation, in which the modulating function of generating the output frequency and output voltage in each phase of the load is realized by cyclic connections of input three-phase windings 14, 15, 17, 18, 20, 21 of three-phase transformers 2-4 to a three-phase supply network 1 at equal intervals of time simultaneously in three phases in a pie chart, and they are disconnected within the direct and reverse half-waves of the input three-phase phases on voltage.

In the frequency converter, the frequency of the output alternating current is determined by the expression f _o = f ₁ -f _c , where f _c is the frequency of the three-phase alternating current network, f ₁ is the repetition rate of the control pulses from the control unit (not shown) to the keys 56, 57, 58, 59, 60, 61.

Thus, if it is necessary to obtain a frequency of 50 Hz at the output of the frequency converter, then the repetition rate of the control pulses to the keys 56-61 should be 100 Hz. If it is necessary to obtain 400 Hz at the output, then the key control frequency 56-61 should be equal to 450 Hz. If the control frequencies and the network are equal, a direct current will be generated at the output. If the control frequency f ₁ is less than f _c , then the phase rotation order will change in the output voltage, and the frequency will be f _out = f _c -f ₁ .

For example, if f ₁ = 40 Hz, then the output will receive a frequency of 10 Hz. Thus, if the load 62-64 (Fig. 1) is, for example, the phase windings of an alternating current motor with a squirrel-cage rotor, then its speed will be controlled up and down from the synchronous one, its reverse will be ensured, as well as its rotation in the other side in the range from zero to a speed close to synchronous.

The voltage amplitude in the phases of the load in the frequency converter is the sum of the voltages generated on all three phase output windings of three-phase transformers 2-4. So for the load phase 62 it will be the sum of the voltages generated by the windings 16, 19, 22. Similarly for the phases of the loads 63 and 64, the output voltage will be the sum of the voltages generated by the windings 30, 39, 48 and 31, 40, 49, respectively.

The number of pulses "n" in the output phase voltage during the period for each frequency is determined by the expression:

where m is the number of input three-phase windings.

The magnitude of the input phase voltage within each pulse is the arithmetic sum of the voltage values of the three pulses generated by the input phase windings of the three transformers related to this phase.

Smooth regulation of the amplitude of the voltage in the phases of the load in the frequency converter is carried out by changing the duration of the on state of electronic switches 56-61 (transistors or thyristors).

In FIG. 2 shows a voltage generation diagram in phase A (U _A ) of the load 62 when the keys 56-61 are on for 90 ° (in a pie chart). In FIG. 3 - the same when the keys 56-61 are turned on for 60 ° (in a pie chart) and in FIG. 4 - the same when the keys 56-61 are on for 30 °.

From the diagrams of FIG. 2-4 it is seen that the shape of the output voltage when it is regulated in the frequency converter remains unchanged. An analysis of this shape of the curve shows that it lacks the 5th and 7th harmonic components, which provides the frequency converter with high energy performance.

Ease of control, a wide and smooth range of frequency and voltage regulation on the load (while maintaining the unchanged shape of the voltage curve in the diagram), the ability to exchange energy between the load and the mains supply the frequency converter can be used in various fields: in a reversible electric drive, high-frequency electric drive, in high-frequency power supplies, in stand-alone power supplies driven by a turbogenerator or diesel generator to provide consumers lektroenergiey with the required frequency and voltage.

Thus, due to the design features of a three-phase-three-phase frequency converter, the invention provides the possibility of increasing the efficiency of the frequency conversion process, expanding the functionality and scope of the frequency converter.

Claims (1)

A three-phase-three-phase frequency converter containing input terminals A, B, C for connecting the mains, output terminals for connecting a three-phase load, three equally made three-phase transformers, each of which includes the first and second input and output three-phase windings, and the initial conclusions of the phase windings the first input three-phase winding and the ends of the phase windings of the second input three-phase winding are connected to the corresponding input terminals A, B and C, and the other terminals of each of the input three-phase windings under are connected to a switching element corresponding to this winding in the form of a three-phase diode bridge with an electronic key in a DC circuit, and the phase windings of the input three-phase windings of one three-phase transformer are connected in series to the input terminals A, B, C, and the phase windings of the input three-phase windings of two other three-phase transformers sequentially connected to the input terminals B, C, A and C, A, B, respectively, while the same phase windings of the output three-phase windings of the three-phase transform tori connected in series in three branches, which are combined in a star circuit and form a three-phase output.

Images