RU2447562C1 - Method for quality and efficiency improvement for electric power use (version 9) - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: compensation of high-order harmonic components is made due to energy reactive component of base frequency harmonic extracted from electric power system by transistor PWM rectifier in the form of energy from sequences of unipolar width-modulated current pulses; length of such pulses is formed according to law of modulating signal variation whereby signal envelope should be proportional to reactive component specified above. At that PWM rectifier is used as additional regulated source of power.

EFFECT: improvement of efficiency use and reduction of non-productive losses of electric power during regulated process of high-order harmonics compensation.

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Description

The method relates to electrical engineering and can be used to increase the efficiency of energy use in the process of controlled compensation of higher harmonic components in a current selected by a non-linear load.

A known method [1] of improving the quality of electricity, adopted as an analogue, in which to “increase the efficiency of use of electric energy, compare the network voltage with the voltage of the reference source of high-quality electric energy, allocate a voltage that is determined by the difference between the voltage of the network and the voltage of the reference source of high-quality electric energy, and the resulting voltage is supplied to consumers of electric energy. " The known analogue method has several disadvantages, one of which is the presence of additional energy costs associated with the use of a "reference source of high-quality electric energy", the power of which is comparable with the power taken by the protected loads. It should also be noted that in the analogue method it is supposed to use voltage combinations: supply and reference, transformation of higher voltage harmonics without "special" means of processing them as a source for extracting higher harmonics, and it is also supposed to utilize voltage harmonics, while it is known that the harmonic components of the current of the fundamental frequency selected by the nonlinear load, whose spectrum does not coincide with the spectrum of voltage harmonics, have a significant effect. In this regard, the known analogue method has low efficiency in relation to solving the problem of reducing the influence of higher harmonics.

A known method [2] of protecting consumers of electricity from the influence of higher harmonic components, which consists in the fact that "generate higher harmonic current components in the network, acting in antiphase with higher harmonics of the main network." The main disadvantage of the known method, adopted as a prototype, is the low energy efficiency, due to the fact that the formation of compensating currents of higher harmonics uses the energy of the main frequency, additionally extracted from the power system. Moreover, the prototype method has low efficiency in relation to the use of electricity. It should also be noted that neither the analog method nor the prototype method provide for the reduction of unproductive power losses in the power system, caused by reactive currents of the fundamental frequency harmonic.

The problem solved by the invention is to increase the efficiency of energy use in the process of adjustable compensation of higher harmonic components in a current selected by a nonlinear load.

This is achieved by the fact that the process of lowering the levels of higher harmonic components, implemented through their compensation, is carried out in the power system due to the reactive component of the harmonic energy of the fundamental frequency.

In this case, the reactive component of the power of the fundamental frequency harmonic is extracted in the form of equivalent energy of a sequence of unipolar, periodically repeating pulse-width modulated current pulses, the duration of which varies according to the law of the envelope of the reactive current of the fundamental frequency extracted from the power system by means of a transistor-type PWM rectifier, and after conversion to DC energy is used to power an additional regulated power source, in which It is recommended to use a PWM inverter, by means of which compensation currents of the group of higher harmonics are formed.

The drawing shows a diagram explaining the essence of the claimed method. The following notation is introduced.

1 - power system

2 - nonlinear load

3 - load current sensor

4 - fully controlled transistor PWM rectifier

5 - capacitive storage

6 - additional adjustable power source

7 - voltage sensor

8 - block generating a logical signal

9 - block generating a modulating signal

10 - harmonic filter of the fundamental frequency

11 - filter harmonics to be compensated

12 - phase inverter

The essence of the method is as follows. As you know, in a power system, when non-linear loads are supplied from it, the following facts take place: the shape of the current is distorted due to the appearance of a group of higher harmonic components of the fundamental frequency in it; a reactive component of the instantaneous harmonic power of the fundamental frequency appears in the power system. The latter fact is due to the fact that part of the energy stored in the electric or magnetic field of the reactive load returns back to the source in the form of a reactive component of the current. The flow of reactive current in inductive loads is provided by the action of self-induction EMF, in capacitive ones - by the energy stored in the electric field of the capacitance. In this case, the signs of the supply voltage and EMF of self-induction, as well as the supply voltage and voltage on the capacitive element, are known to be opposite. The negative effect associated with reactive currents, as is known, consists in additional unproductive energy losses in the power system.

In the inventive method, the task of increasing the efficiency of energy use is solved by reducing its unproductive losses. At the same time, it is proposed, at those times when the load in the power system is reactive, to extract the reactive component of the harmonic current of the fundamental frequency from the power stream and, after conversion, use an additional regulated power source to power, which is proposed to use a PWM inverter. In this case, by means of the latter, due to the extracted reactive energy, a series of compensating currents are generated and generated into the power system, which are equivalent to the currents of the group of higher harmonics generated by the nonlinear load and are in antiphase with respect to them. As a result of the extraction of the reactive component of the current of the fundamental frequency generated by the nonlinear load from the power system, the circuit in which it closes is limited to the connection point of the device that provides its extraction. Thus, the power system is unloaded from the reactive component of power.

The problem of extracting the aforementioned reactive components from the phases of the power system is solved by using a fully controlled n-phase transistor PWM rectifier built on IGBT modules. The flow of reactive currents in each of its arms, in each half-cycle of the supply voltage, is provided by the action of the self-induction EMF or by the voltage on the capacitive component of the load. The use of IGBT transistors for rectification of current allows you to use their control properties relative to currents. In this case, selective rectification of only those current components that are specified by a modulating control signal with specified characteristics is carried out. At the output of the controlled transistor PWM rectifier, there is a sequence of unipolar periodically repeating pulse-width modulated pulses, the energy of which is equivalent to the energy of the reactive component of the current of the fundamental frequency extracted from the power system, and the duration changes according to the law of its envelope generated by the modulating signal.

The method is as follows. Active-reactive nonlinear load 2 selects from the power system together with the active reactive component of energy. In this case, the following facts take place: load 2 loads the power system with reactive current and generates a group of higher harmonics in the power system. Using a current sensor 3 from the power system, a signal is selected proportional to the current supplying the load 2, consisting of a spectrum of higher harmonics and harmonics of the fundamental frequency, which is isolated by the harmonic filter of the fundamental frequency 10. Thus, signals are present at the output of unit 10 and the sensor of the supply voltage 6, proportional, respectively: to the harmonic current of the fundamental frequency and to the supply voltage. In this case, a signal proportional to the reactive current at the output of block 10 generated by load 2 lags behind the voltage supplying it by a certain angle, which determines the power factor in the power system. In the block of formation of the logical signal 8, the signs of the signals arriving at its inputs from the outputs of the current sensor 3 and the sensor of the supply voltage 7 and at its output are compared, and a digital sequence of zeros and ones is formed, and if the signs of the signals are proportional to the current and voltage, the output of block 8 is formed by a logical unit, and in other cases, a logical zero. Thus, a logical unit corresponds to that part of the period during which load 2 selects active power from the power system. Further, the signal from the output of block 8 is fed to one of the inputs of the block for generating the modulating signal 9, the second input of which receives a signal proportional to the harmonic current of the fundamental frequency taken by load 3. Thus, at those moments during which the logic zero coming from the output of block 8 coincides at the input of block 9 with the positive half-wave of the main frequency current taken by load 2, modulating voltage pulses proportional to the reactive component of the current taken by the load are formed at the output of block 9 oh 2, and in-phase with respect to it. During the duration of the voltage pulses generated by block 9, at the control inputs of a fully controlled transistor PWM rectifier 4, the latter is powered by either the self-induction EMF or the voltage on the capacitive component of the load, depending on its nature. Thus, by means of a controlled transistor PWM rectifier 4, the reactive component of the current of the main frequency, selected by the active-inductive load 2, is extracted in a form that contributes to its accumulation. At the same time, a sequence of unipolar, periodically repeating pulse-width modulated current pulses is formed at its output, the duration of which varies according to the law of variation of the envelope of the extracted reactive component of the current. From the output of block 4, a sequence of pulse-width modulated current pulses, through a capacitive storage 5, is supplied to an additional regulated power source 6, which is proposed to use a PWM inverter. In a capacitive storage, said sequence of pulse-width modulated current pulses, whose energy is equivalent to the fundamental frequency harmonic reactive current extracted from the power system, selected by the active-reactive load, is accumulated in the form of direct current energy. The voltage thus obtained is used to power an additional regulated power source 6. In this case, by means of the latter, due to the extracted reactive energy, a series of compensating currents are generated and generated into the power system, which are equivalent to the currents of the group of higher harmonics generated by the nonlinear load and are in antiphase with respect to them . The formation of a series of compensating currents of higher harmonics is carried out by means of a filter of harmonics to be compensated, 11 and a phase inverter 12, in which it is respectively set: the spectrum of compensated harmonics and their phase. This forms the envelope of the modulating control signal of an additional adjustable power source 6.

Thus, as a result of the sequence of actions reproduced in accordance with the claimed method of increasing the efficiency of energy use in the process of controlled compensation of higher harmonic components in a current selected by a nonlinear load, it is achieved that adjustable compensation of groups of higher harmonic components is carried out due to the extracted reactive component of energy .

INFORMATION SOURCES

1. RF patent No. 2320067, published: 2007.01.20.

2. RF patent No. 2294044, published: 2007.02.20.

Claims (1)

A method of improving the quality and efficiency of energy use, in which the group of higher harmonic components in the power flow of the power system is reduced by means of their adjustable compensation, characterized in that the process of adjustable compensation of the group of higher harmonic components is carried out due to the energy of the reactive component of the fundamental frequency harmonic, which is extracted in the form equivalent energy sequences of unipolar, periodically repeating latitudinal modulated current pulses, the duration of which varies according to the law of the envelope of the said reactive component, by means of a proportional modulating signal that controls the transistor-type PWM rectifier and, after conversion to direct current energy, is used to power an additional regulated power source, through which compensating currents equivalent to the currents are formed groups of higher harmonic components and their opposite in phase, moreover, the control of the above tively controllable power source is performed by the modulating signal envelope proportional to the signal which is formed, which is the geometric sum of all the harmonic components to be compensated in the current spectrum bleed nonlinear load.