RU2644034C1 - Method of measurement of the instant reactive power of the three-phase network - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: proposed method relates to the field of electrical engineering and electric power engineering and, in particular, can be used in the systems of centralized monitoring and monitoring of electric power systems, in reactive power compensation systems, in power active filters. Method for determining the instantaneous reactive power of a three-phase network involves the measurement of the instantaneous values of the currents of the three phases and the instantaneous values of the voltages between these phases, the mutual multiplication of these values, after which the summation of the received signals is carried out. As a result, a signal proportional to the instantaneous reactive power of the three-phase network is obtained.

EFFECT: technical result is an increase in the accuracy and speed of measuring the instantaneous reactive power of a three-phase network.

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Description

раз, осуществляемый посредством устройства, содержащего входные зажимы цепи тока и цепи напряжения, подключенные к фазным проводам контролируемой сети, устройства ввода напряжения, три перемножителя, суммирующее устройство и выходное фильтрующее и масштабирующее устройство. К выходу устройства подключено фильтрующее и масштабирующее устройство - фильтр низкой частоты. С помощью данного устройства осуществляют перемножение действующих значений фазных токов и межфазных напряжений и их суммирование по следующей формуле:The proposed method relates to the field of electrical engineering and the electric power industry and, in particular, can be used in centralized control and monitoring systems of electric power systems, in reactive power compensation systems, in active power filters. The following solutions are known in the art in this field. A known method for determining the effective value of the reactive power of a three-phase network, increased in

times, carried out by means of a device containing input terminals of a current circuit and a voltage circuit connected to phase wires of a controlled network, a voltage input device, three multipliers, a summing device, and an output filtering and scaling device. A filtering and scaling device, a low-pass filter, is connected to the output of the device. Using this device, the multiplication of the effective values of phase currents and interphase voltages is carried out and their summation is carried out according to the following formula:

,

,

where Q is the effective value of the reactive power of a three-phase network;

- действующее значение реактивной мощности фазы C;

- the effective value of the reactive power of phase C;

- действующее значение реактивной мощности фазы B;

- the effective value of the reactive power of phase B;

- действующее значение реактивной мощности фазы A.

- the actual value of the reactive power of phase A.

This calculation formula is a traditional scheme for measuring the reactive power of a three-phase network with three barmeters (Copyright certificate No. 1798714, publication date 02/28/1993).

If we imagine u _A , u _B , u _C and i _A , i _B , i _C for a symmetric load in the following form:

then when calculating interphase voltages we get:

where U, I are the effective values of phase voltage and current.

In this case:

where Q _phase is the effective value of the reactive power of the phase.

,Thus, we obtain

,

where Q is the effective value of the reactive power of a three-phase network.

This method is aimed at determining the effective value of the reactive power of a three-phase network only once during a period of electrical voltage. When determining the actual value of reactive power, a filter device is used, which increases the time of such a measurement. The disadvantages of this method is that it includes an integration operation (low-pass filter), which reduces the response speed with a rapid change in the input quantity, which reduces the accuracy of measuring the reactive power of a three-phase network.

A known method of measuring reactive power in reactive power compensation systems, in which the instantaneous values of voltage u (t) and current i (t) are multiplied in the process of returning energy to the network, i.e. the instantaneous values of the signals u ₁ and u _{2 are} not subjected to additional transformations, while maintaining the accuracy of measuring reactive power under both sinusoidal and non-sinusoidal modes of energy consumption (RF patent 2293340, publication date 02/10/2007).

A known method of determining the reactive power of a three-phase network, including measuring the instantaneous currents of two phases and the instantaneous voltage values between these phases and the third phase, multiplying these values to obtain phase powers. Then, the variable components of these works are isolated and integrated from the moment the phase-to-phase voltage passes through zero for a given time interval. When applied to the input bus of the measured signals _{i A (t), U AC} (t) and _{i B (t), U BC} (t) at the output of the first and second multipliers appear signals proportional to the current value of the phase reactive power p _AC (t) _{= U AC (t) ⋅i a} (t), p BC (t) = U BC (t) ⋅i B (t), and the output of low-pass filters - signals proportional to the current values of active and reactive power (RF patent 2263322, publication date 10.27.2005).

The disadvantages of this solution are:

- the presence in the measuring path of filters to isolate the variable components of the phase power, which increases the measurement time;

- the presence of integrating elements at certain time intervals, which also increases the measurement time.

The closest in technical essence to the claimed invention is a method for determining instantaneous reactive power, in which once a period the current amplitude I _sm and voltage U _sm , the values sinϕ of the angle ϕ of the phase shift of the current are measured depending on the integral of the difference between the measured voltage and current, after which carry out the multiplication of these values with obtaining instantaneous reactive power according to the expression:

where m is the number of phases of an electromechanical energy converter (RF patent 2141720, 20.11.1999).

A disadvantage of the known solution is that it is possible to measure the amplitude of current I _sm and voltage U _sm , as well as phase shift only once per period, which leads to low speed and accuracy of measuring the instantaneous reactive power of a three-phase network. Another disadvantage is the presence of integrating elements at certain time intervals, which also reduces the speed of the measurement method.

The objective of the claimed invention is to provide a more advanced method of measuring the instantaneous reactive power of a three-phase network. The value of the instantaneous reactive power of a three-phase network q (t) is an important indicator of the negative impact of the consumer on the quality of electric energy in three-phase networks with an unsteady load.

The technical result of the claimed invention is to improve the accuracy and speed of measurement of reactive instantaneous power of a three-phase network.

The technical result is achieved through the implementation of a method for determining the instantaneous reactive power of a three-phase network, including measuring the instantaneous currents of three phases and the instantaneous voltage values between these phases, mutually multiplying these values, after which the obtained signals are summed, and the output receives a signal proportional to the instantaneous reactive power three-phase network.

. Так, если представить мгновенные значения напряжений между фазами u_AB, u_BC, u_CA и мгновенные значения токов трех фаз и i_A, i_B, i_C в следующем виде:In a particular case, the implementation of the method by summing is carried out with a coefficient equal to

. So, if we imagine the instantaneous voltage values between the phases u _AB , u _BC , u _CA and the instantaneous values of the currents of the three phases and i _A , i _B , i _C in the following form:

then it follows:

where U (t) is the instantaneous value of the voltage module of the three-phase network, I (t) is the instantaneous value of the current module of the three-phase network.

As a result, we get:

where ϕ (t) is the instantaneous angle between the depicting current vector I (t) and voltage U (t) of the three-phase network.

q (t) is the instantaneous reactive power of a three-phase network.

Thus, in the implementation of the corresponding multiplication of the instantaneous values of the currents of each phase i _a , i _b , i _{c of a} three-phase network with instantaneous values of interphase voltages u _bc , u _ca , u _ab , adding the obtained values with a scale factor, as a result, a signal proportional instantaneous reactive power of a three-phase network, it is possible to continuously measure instantaneous reactive power.

The claimed method allows to determine the instantaneous value of the reactive power of a three-phase network without the need for integration and additional smoothing of the obtained value by a filtering device, which leads to an increase in the measurement speed of the instantaneous reactive power of a three-phase network. A reduction in the number of conversion operations in the method leads to an increase in the accuracy of measuring the instantaneous reactive power of a three-phase network in comparison with previously known solutions.

With an unsteady load, the value of the instantaneous reactive power of the three-phase system obtained according to the claimed method makes it possible to instantly monitor the amount of stored electromagnetic energy with high accuracy, for example, in the inductances of three-phase networks with a proportionality coefficient equal to twice the angular rotation frequency of the image current vectors I and voltage U of the three-phase load.

Further, the solution is illustrated by reference drawings:

FIG. 1 is a flowchart of a method for measuring instantaneous reactive power of a three-phase network.

FIG. 2 - examples of oscillograms reflecting the values of instantaneous reactive power and the module representing the three-phase voltage vector.

.In FIG. 1 is a flowchart illustrating a particular case of a method for measuring the instantaneous reactive power of a three-phase network, which consists of multipliers 1, 2, 3 (units for multiplying the instantaneous phase currents with instantaneous interphase voltages) and a scale adder 4 with a summation coefficient equal to

.

In the particular case of the invention, the method is as follows.

. Таким образом, получают сигнал, пропорциональный значению мгновенной реактивной мощности трехфазной системы.Signals are proportional to the instantaneous phase currents i _a , i _b , i _c , and signals proportional to the instantaneous values of instantaneous interfacial voltages u _ab , u _bc , u _ca. Then, the multiplication of the instantaneous values of the phase i _a current instantaneous value of the phase voltage u _bc, multiply the instantaneous phase value of the current i _b to the instantaneous value of phase voltage u _ca, multiply the instantaneous phase value of the current i _c to the instantaneous value of a phase u _ab voltage is then summed obtained signals with a coefficient equal to

. Thus, a signal is obtained proportional to the instantaneous reactive power of the three-phase system.

The claimed method can be characterized by the following expression:

,

,

where i _a , i _b , i _c - instantaneous phase currents;

u _bc , u _ca , u _ab - instantaneous interfacial voltage;

U (t), I (t) - instantaneous modules depicting the voltage and current vectors of a three-phase system;

ϕ is the instantaneous phase shift angle of the imaging current vector I (t) relative to the imaging voltage vector U (t).

In the particular case of implementing the invention, a device may be used to implement the claimed method, comprising three blocks of multiplying 1, 2, 3 instantaneous phase currents with instantaneous interphase voltages, the outputs of which are connected to the inputs of the adder 4 with a scale factor, the output of the adder is the output of the device.

. На выходе сумматора присутствует сигнал, пропорциональный мгновенной реактивной мощности трехфазной системы.The input of the device receives signals proportional to the instantaneous phase currents i _a , i _b , i _c , and signals proportional to the instantaneous values of interphase voltages u _bc , u _ca , u _ab . The phase currents i _a, i _b, i _c appropriately multiplied with signals instantaneous phase voltages u _bc, u _ca, u _ab multiplication in blocks. The resulting expressions are added up in the adder with a summation coefficient equal to

. At the output of the adder there is a signal proportional to the instantaneous reactive power of the three-phase system.

Thus, the claimed method allows you to instantly measure the current value of the instantaneous reactive power of a three-phase network at each moment of time continuously, without any discretization of time, even on the interval of the supply voltage period.

When applying the inventive method on precision (high-precision) analog microcircuits, the measurement time of the instantaneous reactive power signal q (t) is determined by the conversion time of the information signal by an analog microcircuit. This conversion time is very small (see example 1).

Example 1

The response time of the measuring path in the calculation of q (t) is mainly determined by the passband of the analog multiplier and the signal setup time. In the particular case of the ADL 539 L multiplier, the maximum bandwidth is 2 GHz, the multiplication accuracy is 1%, and the signal settling time is 2 ns.

For AD 632 microcircuits, these same parameters are 1 MHz, 0.25%, 2 μs, respectively.

Example 2

In FIG. 2 shows an example of oscillograms obtained by continuously determining the instantaneous reactive power of a three-phase network and the module depicting a three-phase voltage vector in accordance with the claimed method.

The oscillograms show the curves of instantaneous power q (t) and the module representing the voltage vector of the three-phase system u _m (t) when the rectifier load is connected to the switchboard using a cable of a certain length, where q1 (t), um1 are the values measured at the point connecting the load to the power cable; q2 (t), um2 - at the point of connection of the power cable to the distribution panel

The oscillography was carried out at the point of connection to the switchboard and directly at the terminals of the rectifier device. All four parameters q ₁ (t), q ₂ (t), u _m1 , u _{m2 were} recorded simultaneously. The behavior of q (t) is due to commutation of the rectifier elements.

As can be seen from the oscillograms, the behavior of the q (t) curve determines the changes in the magnitude of the module of the depicting vector U (t). By compensating for the variable component q (t) using a power active filter, it is possible to improve the quality of the voltage at the point of its connection to the distribution board.

Thus, the proposed method allows you to continuously convert information about the magnitude of the instantaneous phase currents and voltages and determine the instantaneous reactive power of a three-phase consumer, as well as continuously monitor this value over the interval of the supply voltage period. The claimed method can be used to control and monitor electric power systems, to increase the speed of reactive power compensation systems, as well as in non-linear voltage distortion compensation systems of three-phase systems when using active power filters.

Claims (1)

A method for determining the instantaneous reactive power of a three-phase network, characterized in that the instantaneous values of the currents of the three phases and the instantaneous voltage values between these phases are measured, mutually multiply these values, and then the resulting signals are summed to produce a signal proportional to the instantaneous reactive power of the three-phase network.

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