RU2310972C1 - Commutated synchronous generator with extreme control over non-sinusoidal character of voltage - Google Patents

Abstract

FIELD: electric engineering, possible use for generating stable frequency voltage in electric power plants with alternating speed of rotation of driving engine shaft.

SUBSTANCE: in commutated synchronous generator, minimization of distortions of sinusoidal character of output voltage is ensured due to control over mutual relation time-wise between moments when commutator disables current pair of diametrically opposite clamps of multi-section excitation winding from constant current source and moments when another pair of clamps is connected to it, making it possible to alter harmonic composition of generated voltage. Sensor controls non-sinusoidal character of voltage, suppresses first harmonic of output voltage and outputs average rectified value of all distorting harmonics into computer. Computer realizes extreme control of non-sinusoidal character of voltage, controlling duration of commutator control impulses by means of an appropriate circuit.

EFFECT: reduced distortions of shape of generated voltage in conformable electric power plants.

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Description

The invention relates to electrical engineering and can be used to generate a stable frequency voltage in electric power plants with a variable rotational speed of the drive motor shaft, for example, in wind power plants, small hydroelectric power stations, diesel-electric plants with speed control depending on the load, in electric installations with a marching drive engine.

Known electromechanical energy converter with a semiconductor switch [A. Voldek Electric cars. - L .: Energia, 1978, p.235], in which the rotation of the stator magnetic flux is created as a result of the series connection of the stator winding sections to the direct current source, which is controlled by the rotation of the rotor, using controlled semiconductor valves. This machine is reliable in operation, but when it is used in the mode of an alternating current generator with a stable frequency (at a variable rotor speed), a switch acting in this case as a frequency converter will convert the total output power stream of the machine, which leads to an oversized installed power of the valves, reduces the efficiency of the device and introduces large distortions in the shape of the curve of the generated voltage.

Also known alternator [FR, patent, 2303410, cl. Н02F 9/14, 1976], designed to produce an alternating electric current of constant frequency at a variable speed of rotation of the drive motor shaft and containing a semiconductor switch, a closed multi-section excitation winding, the sections of which are evenly distributed around the stator circumference, are connected in series according to, and their conclusions are connected through a semiconductor switch to a controlled direct current source, a speed sensor mechanically connected to the generator shaft. But this device does not provide stabilization of the frequency of the output voltage and minimization of the non-sinusoidality of this voltage when the rotation speed of the generator shaft is varied over a wide range, since there are no signs in this device aimed at the possibility of alternately connecting the switch with a switching frequency proportional to the sliding frequency of diametrically opposite conclusions of the sections of the multi-section closed field winding to a direct current source.

The closest set of essential features to the proposed device is a switched synchronous generator of stable frequency [RU, patent, 2103800, Н02Р 9/42, 1998], comprising a speed sensor mechanically coupled to the generator shaft, a controlled constant current source, semiconductor switch, power the input of which is connected to the output of a controlled direct current source, a multi-section closed excitation winding, the sections of which are uniformly distributed around the circumference of the inductor, are connected in series In fact, their conclusions are connected to the outputs of the semiconductor switch, which is configured to alternately connect the switch with a switching frequency proportional to the slip frequency and the number of sections of the field winding per pair of poles, diametrically opposite the conclusions of the sections of the field coil to the output of a controlled constant current source, the excitation regulator, the output of which is connected to the input of a controlled DC source, a voltage sensor whose output is connected to the first input of the regulator excitation, and the input is with the output of the generator, a voltage regulator, the output of which is connected to the second input of the excitation regulator, a frequency regulator, a comparison circuit, a comparator, the first inputs of the comparison circuit and comparator connected to the output of the frequency setter, and the second to the output of the speed sensor , a controlled pulse generator, the input of which is connected to the output of the comparison circuit, and a pulse distributor, the first input of which is connected to the output of the comparator. The advantage of the prototype is the ability to maintain a constant frequency of the generated alternating electric voltage in a wide range of rotational speeds. At the same time, the presence of switching sections of the field winding of this electric machine, due to the principle of its operation, entails a slight deterioration in the shape of the curve of the generated voltage due to the appearance of undesirable harmonics in it, the composition of which depends on both the shaft rotation frequency and the magnitude and nature of a randomly varying load. However, the device in question does not minimize the distortion of the shape of the output voltage curve, since the prototype has no signs aimed at realizing this possibility.

The invention is aimed at reducing distortions in the shape of the curve of the generated voltage in power plants with a variable speed of rotation of the shaft of the drive motor based on a switched synchronous generator.

The essence of the invention lies in the fact that from a known switched synchronous generator of stable frequency, the proposed switched synchronous generator with extreme voltage non-sinusoidal control, comprising a speed sensor mechanically coupled to the generator shaft, a controlled DC source, a semiconductor switch, the power input of which is connected to the output of the controlled DC source, multi-section closed field winding, sections of which are evenly distributed around the circumference of the inductor, they are connected in series according to, and their conclusions are connected to the outputs of the semiconductor switch, configured to alternately connect the switch with a switching frequency proportional to the slip frequency and the number of sections of the field winding per pair of poles, diametrically opposite conclusions of the sections of the field coil to the output of a controlled constant source current, the excitation regulator, the output of which is connected to the input of a controlled DC source, voltage sensor, you One of which is connected to the first input of the excitation regulator, and the input is connected to the output of the generator, a voltage regulator, the output of which is connected to the second input of the excitation regulator, a frequency regulator, a comparison circuit, a comparator, the first inputs of the comparison circuit and comparator connected to the output of the frequency regulator, and the second - with the output of the speed sensor, a controlled pulse generator, the input of which is connected to the output of the comparison circuit, and a pulse distributor, the first input of which is connected to the output of the comparator, characterized in that The distortion of the shape of the generated voltage curve is achieved due to the fact that for the purpose of extreme control of the non-sinusoidality of this voltage, a voltage non-sinusoidality sensor is additionally introduced, the input of which is connected to the generator output, a computer whose input is connected to the output of the voltage non-sinusoidal sensor, and a frequency divider whose input connected to the output of a controlled pulse generator, and the output to the second input of the pulse distributor, and a pulse width control circuit s, the clock input of which is connected to the output of the controlled pulse generator, the installation input is connected to the output of the calculator, and the control inputs are connected to the corresponding outputs of the pulse distributor, the outputs of the pulse duration control circuit are connected to the corresponding control inputs of the semiconductor switch.

Figure 1 presents a diagram of a switched synchronous generator with extreme control of voltage non-sinusoidality. The circuit contains three control loops.

The first circuit serves to stabilize the output frequency of the generator 1 with a multi-section closed field winding 2 and includes a speed sensor 3 mechanically connected to the shaft 4 of the generator 1, a comparison circuit 5, a controlled pulse generator 6, a frequency divider 7, a pulse distributor 8, a circuit control the duration of the pulses 9, the semiconductor switch 10 and the generator 1. The desired output frequency is set using the frequency adjuster 11, the signal from which is fed to the first input of the comparison circuit 5. And Information about the current rotational speed of the shaft 4 is supplied from the rotational speed sensor 3 to the second input of the comparison circuit 5. The direction of switching the conclusions of the multi-section closed excitation winding 2 is determined using the comparator 12, the first input of which from the output of the frequency setpoint 11 receives a signal about the required output frequency , the second input from the output of the speed sensor 3 receives a signal about the current speed, and the output of the comparator 12 is connected to the first input of the pulse distributor 8.

The second circuit provides stabilization of the generated voltage and contains a voltage sensor 13 connected to the generator output 14, an excitation regulator 15 controlling the direct current source 16, a semiconductor switch 10 and generator 1. The required output voltage is set using the voltage adjuster 17, the signal with which is fed to the second input of the excitation controller 15.

The third circuit is necessary to reduce distortions in the shape of the generated voltage curve by implementing extreme control and includes a voltage non-sinusoidal sensor 18, connected to the output 14 of the generator 1 by its input, a calculator 19, the input of which is connected to the output of the voltage non-sinusoidal sensor 18, a pulse width adjustment circuit 9, installation the input of which is connected to the output of the calculator 19, the semiconductor switch 10 and the generator 1.

Figure 2 shows the plot of the output voltage of the frequency divider 7 (figure 1) - u _PM , pulse distributor 8 - u _RI1 , u _RI2 , u _RI3 , ..., u _RIm-1 , u _RIm and pulse _width control schemes 9 - u _СРД1 u _СРД2 , u _СРД3 , ..., u _СРДm-1 , u _CPm , and the last diagrams for clarity are shown for two cases: a solid line - for pulse durations t _{and 1} , when the pulses of adjacent outputs overlap each other over time t _CR , and dashed lines for the duration of pulses t _{and 2} , when between pulses of adjacent outputs there are pauses of duration t _PZ .

Figure 3 shows a block diagram of a search algorithm for the operation of the calculator 19 (figure 1), providing extreme control of the non-sinusoidal shape of the curve of the voltage generated by the device. The block diagram indicates: N ₀ is the binary code of the calculator 19, corresponding to the pulse duration at the output of the pulse _width control circuit 9 t _and = t _ИРИ , where t _ИИ is the pulse duration at the output of the pulse distributor 8, i.e. when t _CR = t _PZ = 0 (figure 2); N _min , N _max - binary codes that specify, respectively, the minimum and maximum values of the relative pulse duration τ _and = t _and / t _IRI ; U _N is the voltage supplied to the input of the calculator 19 (Fig. 1) from the output of the voltage non-sinusoidal sensor 18 with a binary code N issued from the output of the calculator 19 to the installation input of the pulse width control circuit 9; and U _N-1 , U _{N + 1} are the voltages supplied to the input of the calculator from the output of the non-sinusoidality sensor 18, respectively, when this binary code N is decreased and increased by one.

Comparison scheme 5 (Fig. 1), a controlled pulse generator 6, a frequency divider 7, a pulse distributor 8 and a comparator 12 together represent a frequency regulator used to control the keys of a semiconductor switch 10. Frequency selector 11, voltage adjuster 17, excitation regulator 15 , speed sensor 3, voltage sensor 13, comparison circuit 5 and comparator 12 can be implemented according to known schemes, including using digital technology. As a controlled pulse generator 6 can be used, for example, a voltage Converter in the frequency of the integral performance. The pulse distributor 8 can be made on the basis of reversible shift registers. The semiconductor switch 10 is built on fully managed double-acting keys, which can be implemented using complementary transistor pairs. The number of two-way keys of the switch 10 corresponds to the number m of sections of the field winding 2 connected to its outputs, which is a multiple of the number of poles 2p. The excitation winding 2 can be structurally designed as an anchor winding of a DC machine.

The voltage non-sinusoidal sensor 18 (Fig. 1) includes a notch filter and a precision rectifier: a notch filter is necessary to suppress the fundamental harmonic of the generated voltage taken from the output 14 of the generator 1 in the third control loop, and the precision rectifier provides an average rectified voltage value containing in its composition the harmonics remaining after suppression by the notch filter of the main one. The notch filter and precision rectifier are implemented according to well-known schemes, including using digital technology.

The calculator 19 (figure 1) provides extreme control of the non-sinusoidal shape of the curve of the generated voltage, can be performed according to well-known schemes, including using digital technology that implements the appropriate methods for finding the extremum [Alexandrov AG Optimal and adaptive systems. - M .: Higher. school., 1989, S. 142-162]. The input of the calculator 19 is fed the average rectified voltage from the output of the precision rectifier, which is part of the generated voltage non-sinusoidality sensor 18. This average rectified voltage is used to indirectly estimate the degree of non-sinusoidality of the generated voltage curve shape, and the control purpose is to ensure a minimum of this average rectified voltage in the entire range of variation as frequency shaft rotation, and the magnitude and nature of the random load.

The control circuit for the duration of the pulses 9 (Fig.1, 2) provides the formation of a control parameter in the third control loop. Why, at the installation input of this circuit, the corresponding code N is supplied from the output of the calculator 19, specifying the required duration t _and key control pulses of the semiconductor switch 10 at its outputs, that is, the required value of the control parameter. The N code entering the installation input is written into binary counters that are part of the pulse width control circuit 9, and the pulses arriving at the clock input of this circuit from the output of the controlled pulse generator 6 increase the counter code with each clock, and overflowing the counters causes the formation of the trailing edge of the control pulses of the keys of the semiconductor switch 10 at the outputs of the control circuit of the pulse duration 9, and the formation of the leading edge of these pulses occurs when dividing the pulses to the control inputs of the pulse width control circuit 9 from the corresponding outputs of the pulse distributor 8. Thus, a larger binary code N corresponds to a shorter pulse duration of the key control and vice versa, moreover, the change in the duration of these pulses is made with discreteness, depending on the digit capacity of the counters, and therefore determining and the accuracy of extreme control of the non-sinusoidal shape of the generated voltage curve. The coordination of the counters of the control circuit for the duration of the pulses 9 and the pulse distributor 8, necessary when changing the frequency of the pulses at the output of the controlled pulse generator 6, is provided by the frequency divider 7.

The rotation of the magnetic flux of the excitation at rotational frequencies of the rotor other than synchronous, in the device according to the invention is created as a result of the series connection of the excitation winding sections 2 (Fig. 1) matched to the sliding frequency to the direct current source 16, similar to the creation of a rotating stator magnetic flux in a known switched synchronous generator stable frequency [RU, patent, 2103800, Н02Р 9/42, 1998]. The winding of the armature of the generator 1 can be performed in the usual versions for synchronous machines, and the power supply of the excitation system of the generator 1 can be carried out both from the output 14 of the device using a controlled rectifier as a direct current source (self-excitation mode of a switched synchronous generator with extreme voltage non-sinusoidal control), and from some independent source, for example, from a separate electric machine exciter located on the same shaft 4 with the generator 1.

The operation of the device is as follows.

Obviously, the principle of generating an output voltage curve in a switched synchronous generator is similar to compiling an output voltage curve from sections of successive input voltage curves in direct semiconductor frequency converters [Dzhuji L., Pelly B. Power semiconductor frequency converters / Transl. from English - M .: Energoatomizdat, - 1983. - 400 p.], Since a switched synchronous generator in the general case can be considered as a set of m conditional synchronous generators, while the generated voltage curve with the desired frequency is formed from sections of the curves of the m-phase symmetrical voltage system [ Semergey S.V. Evaluation of the quality of the output voltage of a switched synchronous generator // News of universities. Electromechanics, - 2004. - No. 4, p.21-24]. However, when this principle is implemented, switching processes take place that determine the presence of distorting harmonics in the generated voltage, i.e. some nonsinusoidal form of its curve. Moreover, in a switched synchronous generator, the harmonic composition of the output voltage depends both on the switching frequency of the outputs of the excitation winding sections, i.e. on the shaft rotation frequency, and on the magnitude and nature of a randomly varying load. In addition, the harmonic composition of the generated voltage will depend on the time relationship of the instant of disconnection of the current pair of terminals of the excitation coil sections from the DC source and the moment of connecting the next next pair of terminals to it. Therefore, by controlling the indicated moments, it is possible to change the harmonic composition of the generated voltage.

In order to minimize distortion of the sinusoidal shape of the output voltage curve, this device implements extreme regulation: the device is considered as a one-parameter extreme object in which the non-sinusoidal shape of the curve of the voltage generated by it is determined by the expression

x = J (β, α ₁ , α ₂ , α ₃ ),

where β is the control adjustable parameter, which is the duration of the control pulses t _{and the} keys of the semiconductor switch 10 formed by the control circuit of the pulse duration 9 (Fig.1, 2), i.e. β = t _and ;

α ₁ (t), α ₂ (t), α ₃ (t) are undefined parameters depending on the switching frequency of the outputs of the sections of the field winding 2, on the magnitude of the electrical load at the output 14 of the generator 1 and on the nature of this load.

To evaluate the non-sinusoidality of the shape of the generated voltage curve in the device using the voltage non-sinusoidality sensor 18 (Fig. 1), the first harmonic _{of the} output voltage U _{1 is} suppressed and the resulting _{average rectified} value of all distorting harmonics U _{dig is obtained} , i.e. x = U _dig .

Changing the duration t _{and the} control pulses of the keys of the semiconductor switch 10 at the outputs of the pulse width control circuit 9 (FIGS. 1, 2) is provided by applying to the installation input of this circuit a corresponding code N from the output of the calculator 19 (FIGS. 1, 3).

Actually extreme control is carried out by the calculator 19, can be implemented by different methods, in particular based on step-by-step algorithms, and is illustrated in Fig. 3 by a block diagram of the simplest version of the search algorithm. From the block diagram it can be seen that the extreme control in the device allows, without identification, α ₁ (t) ... α ₃ (t) to minimize U _dig by finding the corresponding code N, and after finding an extremum of an adjustable value near this extremum, some oscillations are established. The magnitude of these fluctuations, and hence the control accuracy, will be determined by the bit depth of the 9 binary counters available in the pulse duration control circuit, into which the code N is supplied to the installation input of this circuit. And the capacity of these counters will determine the division ratio of the frequency divider 7.

Stabilization of the generated voltage in the proposed device is carried out using the excitation controller 15 by known methods, and stabilization of the output frequency of the generator is similar to the prototype [RU, patent, 2103800, Н02Р 9/42, 1998].

Thus, the proposed switched synchronous generator with extreme control of voltage non-sinusoidality makes it possible to reduce the distortion of the shape of the curve of the generated voltage in electric power plants with a variable rotation speed of the drive motor shaft.

Claims (1)

A switched synchronous generator with extreme voltage non-sinusoidal control, comprising a speed sensor mechanically coupled to the generator shaft, a controlled DC source, a semiconductor switch, the power input of which is connected to the output of a controlled DC source, a multi-section closed excitation winding, the sections of which are uniformly distributed around the circumference inductor, connected in series according to, and their conclusions are connected to the outputs of the semiconductor switch made with the possibility of alternately connecting the switch with a switching frequency proportional to the slip frequency and the number of sections of the field winding per pair of poles, diametrically opposite conclusions of the sections of the field coil to the output of a controlled constant current source, the excitation regulator, the output of which is connected to the input of a controlled constant current source, sensor voltage, the output of which is connected to the first input of the excitation regulator, and the input is connected to the output of the generator, a voltage regulator, the output of which connected to the second input of the excitation controller, a frequency adjuster, a comparison circuit, a comparator, the first inputs of the comparison circuit and a comparator connected to the output of the frequency setter, and the second to the output of the speed sensor, a controlled pulse generator, the input of which is connected to the output of the comparison circuit, and pulse distributor, the first input of which is connected to the output of the comparator, characterized in that in order to extreme control the non-sinusoidality of the generated voltage, an additional non-sinuso sensor is introduced voltage identifier, the input of which is connected to the output of the generator, the calculator, the input of which is connected to the output of the non-sinusoidal voltage sensor, the frequency divider, the input of which is connected to the output of the controlled pulse generator, and the output to the second input of the pulse distributor, and the pulse width control circuit, clock input which is connected to the output of the controlled pulse generator, the installation input is with the output of the calculator, and the control inputs are with the corresponding outputs of the pulse distributor, the outputs pulse width control circuits are associated with the corresponding control inputs of the semiconductor switch.

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