RU2591031C2 - Method for determination of consolidated primary parameters of power transmission line by four-terminal element - Google Patents

Abstract

FIELD: electricity; data processing.

SUBSTANCE: invention can be used during functional check and diagnosing of power transmission line (PTS) based on the theory of multipole devices. Method consists in replacement of the entire single-wire power transmission line or one linear wire of a multi-wire power transmission line, making part of a symmetrical power system, along the whole length in combination with an accompanying linear valves and a four-pole device, in experimental determination of its longitudinal and transverse parameters. Active and reactive resistances and conductivities making part of the L-shaped equivalent circuit of the four-pole device, replacing a linear wire of a power transmission line, are determined in two experiments: idle movement and short circuit. As a result of analytical processing of the experimental data there are determined consolidated longitudinal and transverse parameters of the power transmission line.

EFFECT: increased reliability of determination of consolidated primary parameters of the power transmission line.

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Description

The invention relates to the field of information processing systems and can be used for functional control and diagnosis of power transmission (transmission lines) based on the theory of multipoles.

A known method of determining the current primary and secondary parameters of a power line to build its direct L-shaped adaptive model [1], selected as a prototype, which consists in the fact that they measure the instantaneous values of voltage and current signals. These arrays of samples of instantaneous values of current and voltage at the beginning and at the end of power lines, obtained at the same time with a certain sampling step, are transmitted from the end of the line to its beginning through the communication channel. Further on the measured arrays of samples of current and voltage, pairs of digital samples of currents and voltages are stored. Then determine the loss of active power on the active resistance of the longitudinal branch of the power transmission line, while simultaneously determining the effective value of the current signal in it and the loss of reactive power on the reactance of this branch. Next, determine the values of the active and reactive resistances of the longitudinal branches of power lines. Then determine the loss of active power on the active resistance of the transverse branch of the power transmission line, while simultaneously determining the effective values of the current signal in it and the loss of reactive power on the reactance of this branch. Next, determine the values of the active and reactive resistances of the transverse branches of power lines. Then determine the numerical values of the attenuation coefficients of the current and voltage and the numerical values of the coefficient of the phase shift of the current and phase shift of the voltage. Next, determine the numerical values of the active and reactive resistances of the longitudinal and transverse branches of the power transmission line, as well as the attenuation and phase-shift coefficients of the voltages and currents per unit length of the power line.

The reliability of the results obtained with this patent is possible only with absolute synchronization of the measurement of instantaneous values of voltages and currents at the beginning and at the end of the line. Technically, this is difficult to do.

In the theory of electrical engineering, an analytical method is known for determining the secondary parameters of a homogeneous section of a single-wire [2], two-wire, three-wire, and four-wire [3] power transmission line. They are quite suitable for an absolutely homogeneous section of a transmission line of negligible length. For heterogeneous power lines, which are real power lines with a very noticeable length (several tens, hundreds and even thousands of kilometers), this method gives only indicative results. Moreover, in this case it is not possible to take into account the influence of linear reinforcement, which is distributed in a significant amount over almost all modern power lines, on the distribution of electrical energy over these power lines.

Representation of a homogeneous section of power lines in the form of a four-terminal network is widely used in electrical engineering and the method of determining the parameters of power lines through the coefficients of a four-terminal network [2]. But this is true only for a homogeneous section of a single-wire power transmission line of elementary length.

Absolute homogeneity, in principle, does not have a single transmission line of noticeable length.

The four-terminal can replace the entire power lines of a noticeable length of a single-wire version. A substituted power line may have a pronounced heterogeneity, it may include associated linear reinforcement.

A four-terminal substitution can also be used for a multi-wire power transmission line, which is part of a symmetrical electric power system. For example, for a three-wire power transmission line. In it, the transfer of electrical energy is carried out by three equal pairs of waves of the electromagnetic field [4]. Therefore, analysis of the transmission of electric energy through it can be performed for one line wire. The conversion processes occurring in this case in all linear wires are completely identical.

The objective of the invention is the formation of a simple, informative and reliable method for determining the enlarged primary parameters of the current power transmission line of single-wire execution, as well as the current power transmission line of multi-wire execution, which is part of a symmetrical electric power system, namely, enlarged longitudinal and transverse parameters.

The technical result consists in the reliable determination of the enlarged primary parameters of the power line, namely, the enlarged longitudinal and transverse parameters as a result of the experiments of idling and short circuit

The technical result is achieved by the fact that a single-wire or multi-wire power line, which is part of a symmetrical electric power system, is replaced by a four-terminal network, in the experimental determination of its input impedances of idling and short circuit as a result of two experiments and as a result of analytical processing of the information thus obtained, enlarged longitudinal and transverse power line parameters.

Thus obtained numerical values of the enlarged primary parameters of power lines are the expected result of the implementation of this invention.

The simplicity and reliability of the proposed method is achieved by direct measurement of electrical quantities, allowing to obtain information about the images of the current values of the input and output voltages and currents on the complex plane, which are the source data for determining the enlarged primary parameters of the analyzed transmission line.

The proposed method is informative due to the fact that, if necessary, it is possible to determine the enlarged primary parameters of power lines per unit length of the line.

The incident and reflected waves of the electromagnetic field act in the aisles of the boundaries of homogeneity. In a real power line, there can be several such boundaries. The boundaries of homogeneity can be: changes in the chemical composition and cross-section of linear wires, changes in terrain, transposition, sagging wires, supports, changes in soil composition, linear reinforcement, etc. It turns out that over the entire length of a real power transmission line, electric energy is transmitted by several groups of pairs of electromagnetic field waves. The procedure for representing the entire power line in the form of a single four-terminal network combines all homogeneous sections, all groups of wave pairs into one resulting one. Therefore, the secondary parameters illustrating the effect of the resulting pair of waves of the electromagnetic field, it is advisable to consider enlarged.

In fig. 1 is a structural diagram of an algorithm for determining enlarged primary parameters of a single-wire power line using the four-terminal method.

In fig. Figure 2 shows the execution scheme of a series of experiments to determine the numerical primary parameters of power lines.

In block 1 (Fig. 1), the procedure for representing a real single-wire power line in the form of a single four-terminal network is performed.

The equivalent circuit of this quadrupole is adopted L-shaped.

The numerical values of the parameters of the four-terminal equivalent circuit, which are enlarged primary parameters of the analyzed power lines, can also be determined as a result of a series of experiments from two experiments.

To determine the numerical values of the enlarged primary parameters of a single-wire power transmission line, it is necessary to perform a series of experiments according to the scheme shown in Fig. 2. The circuit includes a voltmeter PV, an ammeter RA, a power meter PW and a capacitor C of small capacity; 2 (two) switching devices (switches) S1 and S2 were used. Here, an electric power system can be used as a source of electric energy, and best of all, an autonomous source of three-phase electric energy, preferably a reduced voltage, indicated in the diagram as EMF Ė.

The experiments are carried out with the direct connection of a four-terminal, replacing a single-wire power line or one linear wire of a multi-wire power line, which is part of a symmetric electric power system (Fig. 2). In this case, the electric power source Ė is connected to the input terminals mn.

When performing the idle test (block 2 in Fig. 1), the keys S1 and S2 must be open. Moreover, İ _{k + 1} = 0.

The ratio of the voltmeter PV and the ammeter RA will determine the input resistance of idling

The active (resistive) component of the input idling resistance is defined as follows:

where P is the reading of the PW power meter.

The reactive component of the input idling resistance:

.

.

In the form of an image on a complex plane, the input idle resistance can be written as follows:

The reactive component of the input idling resistance can have both inductive (positive imaginary part in equality (1)) and capacitive (negative imaginary part in equality (1)). To clarify its nature, a small power capacitor C should be connected to the input terminals of the power transmission line under study for a short time. But only at the time of recording changes in the readings of the ammeter of the RA. An increase or decrease in these readings will determine the nature of the input impedance.

The value of the input current is determined by the formula:

,

,

where I _1a and I _1p are the active and reactive components of the input current.

When connecting to the input terminals of the analyzed power lines by short-circuiting the S2 key (Fig. 3) of a capacitor C of a small capacity, the input current value will be determined somewhat differently:

where I _C is the current value in the branch with capacitor C, which is appropriate here to be considered idealized.

From formula (2) it follows that if the input idle resistance is active-inductive, then when the capacitor C is turned on, the input current decreases, and if the input resistance is active-capacitive, then when the capacitor C is turned on, the input current increases.

The experience of a short circuit with direct connection of a four-terminal, replacing a single-wire power line, is performed in block 3 (Fig. 1) with a reduced input voltage by shorting the key S1 (Fig. 3). The key S2 must be open.

The input short-circuit resistance with direct connection of the four-terminal device determines the enlarged longitudinal parameters of the analyzed power lines:

.

.

On the substation schemes of power lines, most often the longitudinal parameters of power lines are usually active-inductive, and transverse and active-capacitive. But with a change in frequency, the nature of the longitudinal and transverse parameters of the power lines can change [5]. In addition, the nature of these parameters can change under the influence of concomitant linear reinforcement, which can be part of the power transmission line under study, and, therefore, as part of the four-terminal substitute for it.

You can clarify the nature of the longitudinal parameters with the help of an additional capacitor C, according to the technique used in the no-load test. This is done in block 4 (Fig. 1).

The enlarged transverse parameters of a single-wire power transmission line are defined in block 5 (Fig. 1) as the reciprocal of the difference between the water resistance of idling and longitudinal parameters:

.

.

The active and reactive components of the enlarged transverse parameters are defined as the real and imaginary parts of these parameters, respectively:

;

;

.

.

The numerical values of enlarged primary parameters determined in this way can be used in calculating the numerical parameters of the secondary parameters of the power transmission line under study [3]. Performed by the proposed method will provide a forecast of voltage and current at the beginning or at the end of a single-wire power transmission line with high reliability [3].

Information sources

1. Dzhumik D.V., Goldstein E.P. A method for determining the current primary and secondary parameters of a power line to build its direct L-shaped adaptive model. Patent No. 2334990, Russia. MKI G01R 25/00. - Tomsk Polytechnic University. No. 2007117275/28; 05/08/2007.

2. Bessonov L.A. Theoretical foundations of electrical engineering. - M.: Higher School, 1967. - 778 p.

3. Bolshanin G.A. Distribution of electric energy in sections of electric power systems. In 2 kn. - Bratsk: BrSU, 2006 .-- 807 p.

4. Bolshanin G.A., Bolshanin L.Yu., Maryasova E.G. Electric energy transmission through a homogeneous section of a three-phase power transmission line of three-wire design, which is part of a symmetric EPS // Bulletin of Irkutsk State Technical University. 2011, 10 (57). - S. 179-186.

5. Arrillag J., Bradley D., Bojer P. Harmonics in electrical systems / Per. from English - M .: Energoatomizdat, 1990 .-- 320 p.

Claims (1)

The method for determining the enlarged primary parameters of a power line by the four-terminal method, which consists in replacing a single-wire power line or one linear wire of a multi-wire power line, which is part of a symmetrical power system, with a four-terminal, in the experimental determination of its integrated primary parameters, characterized in that the entire power line is replaced by a four-terminal along the entire length in conjunction with the associated linear reinforcement, The enlarged primary parameters of the power line are determined as a result of two experiments, the idling experience and the experience of short circuit when the power line is turned on directly, as a result of the analytical processing of the information obtained in this way, the longitudinal and transverse parameters of the power line, as well as their active and reactive components, are determined.

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