RU2160962C2 - Method of signal transmission and reception in three-phase electric network - Google Patents

Abstract

FIELD: electrical engineering. SUBSTANCE: method can find use in organization of communication channels with employment of 0.38, 10.0, 35.0-110.0 kV power lines without communication processing by high-frequency rejecters. Invention solves problem of increase of noise immunity and speed of transmission of signals up to 50 or 100 baud. Synchronous detection of signals with use of integration whose start and finish are determined by characteristic points which are time moments of transition of common voltage through zero at transmission and reception centers is employed in proposed method. EFFECT: increased noise immunity and speed of transmission of signals. 1 dwg

Description

 The invention relates to the field of electrical engineering and can find application in organizing communication channels using a three-phase electric network / 0.38-10-35-110 / kV without its processing by high-frequency chokes, while the transmission and reception of signals is carried out on the side of 0.38 kV.

 A known method of transmitting and receiving signals in a three-phase electric network, which is implemented in the device by AS USSR N 1737481 A1, G 08 G 19/12, 1992. The disadvantages of this method are the low noise immunity when receiving signals and low, no more than 10 Baud, signal transmission speed.

 Closest to the claimed method is a method of transmitting and receiving signals in a three-phase electric network, which is implemented in the patent for invention N 2061256 class. 6 G 08 G 19/12, 1996 / prototype /. This method has the same disadvantages.

 The claimed method solves the problem of increasing the noise immunity of signal reception when a new technical result is achieved - increasing the signal transmission rate to 50 or 100 Baud.

In the claimed method of transmitting and receiving signals in a three-phase electric network, the supply point U (t) of industrial frequency F / supply voltage / is converted into signal currents flowing respectively in phases A, B, C at a transmission point:
i _A (t) = 2I _m sinΩt • cosω ₀ t;
i _B (t) = 2I _m sin (Ωt-120 ^° ) • cosω ₀ t;
i _C (t) = 2I _m sin (Ωt-240 ^° ) • cosω ₀ t,
where 2I _m is the amplitude of the beat current,
Ω = 2πF;
ω ₀ = nΩ,
where n >> is a positive integer.

These currents are transmitted to the receiving point, where the signal currents in phases A, B, C are converted to the signal voltage U ₀ (t) = U _m0 • cosω ₀ t; form from voltage U (t) the voltages of the first and second local oscillators, respectively, U _r1 (t) = U _{mr1 cosω 0} t; Where U _{mg1, mg2 U, U r2 (t) = U} mr2 cos2ω ₀ t; U _m0 , U _m2 - voltage amplitudes, multiply the stresses U ₀ (t) and U _r (t), isolate, by filtering, the voltage U ₂ (t) = U _m2 cos2ω ₀ t, multiply the stresses U _r2 (t) = Um _r2 cos2ω ₀ t and U ₂ (t) extract, by filtering, the constant component U _n , integrate U _n in the time interval 0≤t≤T, where T = 0.02 s at a signal transmission rate of 50 Baud and T = 0, 01 s at a signal transmission rate of 100 Baud, while the beginning and end of the signal transmission and integration operations, respectively, correspond to single instants of the transition time of the supply voltage through zero at the transmission points and at ma.

 The increase of noise immunity when receiving signals in the claimed method is carried out through the use of synchronous detection with subsequent integration of the simultaneous voltage, while it is possible to receive signals with a signal / noise ratio of less than one. This is because in the claimed method there is no suppression of a weak signal by a stronger signal / interference /. Therefore, the quality of the communication channel is practically independent of the signal-to-noise ratio / A.P. Manovtsev. Introduction to digital radio telemetry. Energy. M., p. 242 /.

 Achieving the technical result - increasing the transmission speed to 50 or 100 Baud is carried out due to the availability of information at the receiving point about the beginning and end of signal transmission, which allows you to correctly select the beginning and end of the integration interval 0≤t≤T at characteristic points corresponding to common points in transition time supply voltage through zero at the points of transmission and reception.

 The device (see drawing) that implements the claimed method, contains in the transmission point a characteristic points synchronizer 1 / synchronizer /, a passive-active type transmitter 2, a three-phase electrical network 3, contains a three-phase rectifier bridge 4, a resistor 5, a capacitor 6 at the receiving point, transformer 7, narrow-band filter / UPF / 8, multiplier 9, UPF 10, transformer 11, phase shifter / FV / 12, converter 13, UPF 14, FV 15, synchronizer 16, multiplier 17, UPF 18, multiplier 19, low-pass filter 20 , integrator 21.

 The system operates as follows.

 The synchronizer 1 generates, at the point of transmission, pulses at the moments of the transition of the supply voltage U (t) / for a special case, phase A - ground / through zero. Pulses follow with a period of T = 0.02 s at a signal transmission rate of 50 Baud and T = 0.01 s at a signal transmission rate of 100 Baud.

Примечание: Если раскрыть /1/, то следует, что в сеть вводят, как и у прототипа, ток сигнала обратной последовательности i₂(f₁) на частоте f₁ и ток прямой последовательности i₁(f₂) на частоте f₂, где индексы 1, 2 соответственно определяют ток прямой и обратной последовательностей
Ω = 2πF;
Ω₀ = 2πf₀ = Ω•n;
n >> 1 - натуральное число,
2Im - амплитуда тока биения колебаний.The beginning and end of signal transmission coincides with the moments when the supply voltage passes through zero. When the passive-active type 2 transmitter is operating, the following signal currents are formed in its phase wires A, B, C:

Note: If you open / 1 /, it follows that the network is injected, like the prototype, the signal current of the negative sequence signal i ₂ (f ₁ ) at a frequency f ₁ and the current of the direct sequence i ₁ (f ₂ ) at a frequency f ₂ , where indices 1, 2 respectively determine the current of the forward and reverse sequences
Ω = 2πF;
Ω ₀ = 2πf ₀ = Ω • n;
n >> 1 is a natural number,
2Im is the amplitude of the beat current.

 Due to the fact that the signal processing at the reception point is carried out in a different way than in the method adopted for the prototype, a more convenient form for analyzing the implementation of the claimed method is to record the signal currents, according to / 1 /.

где I_m = 0,5 амплитуды токов биения колебаний согласно /1/
/Л. А. Бессонов Теоретические основы электротехники. - М, Энергия, 1978 г., 305 с./
Для заявленного способа представляет интерес только ток с частотой сигнала ω₀, т.е. согласно /2/ ток сигнала равен

В дальнейшем токи с комбинационными частотами

и т.д. будут отфильтрованы фильтром частоты Ω₀-8.
Элементы трехфазного выпрямительного моста 4 выполняют следующие функции: через резистор 5 протекает постоянная составляющая выпрямленного тока частоты F. Конденсатор 6 и индуктивности обмоток трансформатора 7 образуют последовательный L, C контур, который настраивают в резонанс на частоту ω₀. Напряжение сигнала U₀(t) на выходе фильтра частоты ω₀-8 с учетом /3/ и значений коэффициентов передачи элементов устройства равно
U₀(t) = U₈(t) = U_m0cosω₀t. (4)
Напряжение сигнала /4/ подают на первый вход умножителя 9. Элементы устройства /чертеж/ 3-8 образуют приемный тракт сигнала.The currents / 1 / are transmitted through the network 3 to the receiving point, which are fed to the inputs of the three-phase rectifier bridge 4. The currents in the secondary winding of the transformer 7 - i ₇ (t), which serves for galvanic isolation from the mains voltage U (t), and taking into account of the fact that the diodes of the bridge 4 open the supply voltage U (t), the frequencies F have the form

where I _m = 0.5 the amplitude of the currents of the beat of oscillations according to / 1 /
/ L. A. Bessonov Theoretical Foundations of Electrical Engineering. - M, Energy, 1978, 305 p. /
For the claimed method, only current with a signal frequency ω ₀ is of interest, i.e. according to / 2 / the signal current is

Further currents with combination frequencies

etc. will be filtered by a frequency filter Ω ₀ -8.
The elements of the three-phase rectifier bridge 4 perform the following functions: a constant component of the rectified current of frequency F flows through the resistor 5. The capacitor 6 and the inductance of the transformer windings 7 form a series L, C circuit, which is tuned to the frequency ω ₀ in resonance. The signal voltage U ₀ (t) at the output of the frequency filter ω ₀ -8 taking into account / 3 / and the values of the transmission coefficients of the elements of the device is
U ₀ (t) = U ₈ (t) = U _m0 cosω ₀ t. (4)
The signal voltage / 4 / is supplied to the first input of the multiplier 9. The elements of the device / drawing / 3-8 form the receiving signal path.

Consider the path of generating the local oscillator voltage U _r (t) at the receiving point. Mains voltage / for a special case, phase A - ground / is supplied to step-down transformer 11. From its secondary winding receive voltage
U ₁₁ (t) = U _m11 cosΩt, (5)
where U _m11 are the amplitudes of the voltage.

где 2U_m13 - максимальное значение "меандра".The voltage / 5 / is fed through PV-12 to the input of the converter 13, from the output of which / for the particular case when n is an odd number / form a meander-type voltage, which can be mathematically expressed in coordinates:
Y axis - U ₁₃ (t)
X axis - t

where 2U _m13 is the maximum meander value.

where T _F = 0.02 s is the period of the frequency F.

Таким образом, напряжение /7/ имеет напряжение постоянной составляющей и набор напряжений с нечетными гармониками частоты Ω-3Ω,5Ω...nΩ. Фильтром частоты ω₀-14 выделяют напряжение с заданной нечетной гармоникой n частоты Ω, т.е. ω₀ = nΩ.
На выходе фильтра частоты ω_o-14 имеют напряжение гетеродина
U_r1(t) = U₁₄(t) = U_mr1•cosω₀t. (8)
Фазовые набеги в устройстве устраняют ФВ-12. Напряжение первого гетеродина /8/ подают на второй вход умножителя 9. Известно, что при подаче на входы умножителя напряжений с одинаковыми частотами ω₀ =ω_r1 и фазами φ₀ = φ_r1 на его выходе имеют напряжение:
U₉(t) = U_m0K₁cosω₀t+U_m0K₂cos2ω₀t+U_m0K₂, (9)
где K₁ и K₂ - коэффициент преобразования умножителя 9.Having expanded in a Fourier series / 6 /, have

Thus, the voltage / 7 / has a DC voltage and a set of voltages with odd frequency harmonics Ω-3Ω, 5Ω ... nΩ. With a frequency filter ω ₀ -14, a voltage with a given odd harmonic n of frequency Ω is isolated, i.e. ω ₀ = nΩ.
The output of the frequency filter ω _o -14 have a local oscillator voltage
U _r1 (t) = U ₁₄ (t) = U _mr1 • _{cosω 0} t. (eight)
Phase raids in the device eliminate the FV-12. The voltage of the first local oscillator / 8 / is supplied to the second input of the multiplier 9. It is known that when voltage is applied to the inputs of the multiplier with the same frequencies ω ₀ = ω _r1 and phases φ ₀ = φ _r1 they have the following voltage at its output:
U ₉ (t) = U _m0 K ₁ cosω ₀ t + U _m0 K ₂ cos2ω ₀ t + U _m0 K ₂ , (9)
where K ₁ and K ₂ - conversion factor of the multiplier 9.

U _m0 is the amplitude value.

 It should be noted that the choice of the value n >> 1 has a limitation that determines the length of the three-phase electric network - L.

где λ - длина волны.So that wave processes do not occur in the line (in this case, it is necessary to install barriers)? the condition must be met

where λ is the wavelength.

To transmit signals on 10/35/110 kV lines, the following frequency range is usually accepted:
500 Hz ≤ f ₀ ≤ 2000 Hz, (11)
with 10 ≤ n ≤ 40.

т. е. чем больше частота обработки, тем выше качество обработки сигнала. Условие /12/ невыполнимо при малых значениях n. Так, при скорости передачи сигналов 100 Бод, т.е. T = 0,01 с и f₀ = 500 Гц (n = 10) неравенство /12/ не будет выполняться. Примем частоту обработки сигнала 2f₀. При этом неравенство /12/ будет иметь вид
0,01 >> 0,001, (13)
что вполне допустимо.On the other hand, for optimal signal processing using integration, it is necessary to fulfill the condition

i.e., the higher the processing frequency, the higher the signal processing quality. Condition / 12 / is not feasible for small values of n. So, at a signal transmission rate of 100 Baud, i.e. T = 0.01 s and f ₀ = 500 Hz (n = 10) inequality / 12 / will not be fulfilled. We take the signal processing frequency 2f ₀ . Moreover, the inequality / 12 / will have the form
0.01 >> 0.001, (13)
which is quite acceptable.

The second term of the expression / 9 / has a frequency of 2ω ₀ . Using UPF 10 emit voltage U ₂ (t) of this frequency:
U ₂ (t) = U ₁₀ (t) = U _m2 cos2ω ₀ t. (14)
This voltage is applied to the first input of the multiplier 19.

The voltage U _g1 (t) is also supplied to two inputs of the multiplier 17. At its output, by analogy with / 3 /, they have a voltage
U ₁₇ (t) = U _m0 K ₃ cosω ₀ t + U _m0 K ₄ cos2ω ₀ t + U _mo K ₄ , (15)
(I. Gonorovsky, Radio Engineering Circuits and Signals. Part II, M-: Soviet Radio, 1961, p. 144),
where K ₃ and K ₄ are the conversion factors of the multiplier 17.

Using UPF 18 isolate the voltage of the second local oscillator with a frequency of 2ω ₀ .
U _r2 (t) = U ₁₈ (t) = U _mr2 cos2ω ₀ t. (16)
This voltage is supplied to the second input of the multiplier 19. The voltage at its output has the form
U ₁₉ (t) = U _m0 K ₅ cos2ω ₀ t + U _m0 K ₆ cos4ω ₀ t + U _m0 K ₆ ,
where K ₅ and K ₆ are the conversion factors of the multiplier 19.

Using a low-pass filter 20 emit a constant component voltage U _m0 • K ₆
U _n = U ₂₀ = U _m0 • K ₆ ;
This voltage is supplied to the first input of the integrator 21. At its second input, pulses of the synchronizer 16 are supplied, and with the help of PV 15, these pulses are simultaneously followed by the pulses of the synchronizer 1. The frequency ω ₀ , for starting the passive-active type 2 transmitter, is formed from the frequency Ω = 2πF is similar to the formation of the frequency ω ₀ = nΩ in the path of the first local oscillator.

The increase of noise immunity when receiving signals is provided as follows:
1. The voltage U _n at the input of the integrator 21 is unipolar in the integration time interval O≤t≤T.

Возможность приема сигналов при отношении сигнал/помеха меньше, чем в прототипе, доказывает достижение поставленной цели - повышение помехозащищенности приема сигналов.2. The interference voltage U _interference (t) on the integration time interval O≤t≤T has a variable / fluctuating around zero / component with the expected value:
M [U _interference (t)] = O
3. Fulfill the condition:

The ability to receive signals with a signal to noise ratio is less than in the prototype, proves the achievement of the goal - increasing the noise immunity of signal reception.

 A new technological result was obtained - the signal transmission rate was increased to 50 or 100 Baud.

Claims (1)

A method of transmitting and receiving signals in a three-phase electric network, according to which the supply voltage U (t) of industrial frequency F is converted into signal currents flowing in phases A, B, C, respectively:
i _A (t) = 2I _m sinΩtcosω _o t
i _B (t) = 2I _m sin (Ωt-120 ^° ) cosω _o t
i _C (t) = 2I _m sin (Ωt-240 ^° ) cosω _o t
where 2I _m is the amplitude of the beat current, Ω = 2PF, ω _o = 2Пf _o = Ωn, n >> 1 is a natural number, ω _o is the passive-active type transmitter start frequency, П = π, signal currents are transmitted to the receiving point characterized in that at the reception point the signal currents in phases A, B, C are converted to the signal voltage U _o (t) = U _mo cosω _o t, where U _mo is the voltage amplitude, form at the reception point from voltage U (t) voltage of the first and second local oscillators, respectively:
U _g1 (t) = U _{mg1 cosω o} t and
U _g2 (t) = U _mg2 cos2ω _o t,
where U _mg1 and U _mg2 are the amplitudes of the voltages, the stresses U _o (t) and U _g1 (t) are multiplied, the voltage U ₂ (t) = U _m 2cos2ω _o t, where U _m2 is the voltage amplitude, is multiplied by the voltage U _g2 (t) and U ₂ (t), isolate the constant component U _n by filtration, integrate U _n in the time interval 0 <t <T, where T = 0.02 s at a signal transmission rate of 50 Baud and T = 0, 01 s at a signal transmission rate of 100 Baud, while the beginning and end, respectively, of signal transmission and integration operations correspond to single moments of the transition voltage of the supply voltage U (t) h through zero at the points of transmission and reception, while the condition

e