RU2111611C1 - Method for receiving and transmitting signals in three-phase power mains - Google Patents

Abstract

FIELD: electrical engineering; organizing communication channels in electric power mains without using high-frequency traps. SUBSTANCE: channels can be organized in lines rated 0.38, 10, 35, and 110 kV. Signal transmission speed can be raised to 50 bands. Method employs PCM-PM system with integration at characteristic points which are time instants when supply voltage crosses zero. Device has two passive-active transmitters, four symmetrical-component voltage filters, two multipliers, two mixers, two low-frequency filters, two integrators, two synchronizers, heterodyne, and inverter. EFFECT: improved signal transmission speed. 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 processing it with high-frequency chokes.

 A known method of receiving and transmitting signals in a three-phase electric network (ed. St. N 1107750). The disadvantage of this method is the low speed signal transmission.

 There is also a known method of transmitting and receiving signals (Scientific and Technical Bulletin on Electrification of Agriculture, Issue 2/54, M., VIESH, 1985, “Communication channel at tonal frequencies along the 10 kV line.” K.I. Gutin and S.A. . Tsagareishvili), where a three-phase electric network is used to transmit signals from controlled points to a control center. The signals are tonal frequency pulses. In this communication channel, a passive-active type transmitter (prototype) is used. The disadvantage of this method is the low noise immunity.

 The present invention solves the problem of increasing the transmission speed of signals in a three-phase electric network with the achievement of a technical result - transmission of signals at a speed of 50 Baud.

In the inventive method, when transmitting the symbol "1" at the transfer point, the industrial frequency voltage F is converted to the negative sequence current at a frequency f ₁ and the direct sequence current at a frequency f ₂ , these currents are transmitted through a three-phase electric network to the receiving point.

The following operations are again introduced: at the receiving point, currents at frequencies f ₁ and f _{2 are} converted to voltage
U ₁ (t) = U _m1 cosnΩt, (n = 1,2, ...., n-1, Ω ≡ 2πF),
convert the voltage of the industrial frequency F to the local oscillator voltage U _g (t) = U _mg cosnΩt, convert the voltages U ₁ (t) and U _g (t) to a constant positive voltage U ₁ , integrate the voltage U ₁ over the interval T ₁ (T ₁ = τ ₁ , τ ₁ - the duration of the transmission of the symbol "1"), the signal corresponding to the symbol "1" is isolated, while the beginning and end of the integration interval T _{1 is} combined with the beginning and end of the transmission of the symbol "1".

When transmitting the symbol "0", the following operations were again introduced: at the point of transfer, the voltage of the industrial frequency F is converted to the current of the negative sequence at frequency f ₃ and the current of the direct sequence at frequency f ₄ , these currents are transmitted via a three-phase electric network to the receiving point, and the currents frequencies f ₃ and f ₄ into a voltage U ₂ (t) = U _m2 cos (nΩt - 180 ^o ), convert the voltage U ₂ (t) and U _g (t) into a constant negative voltage U ₂ in the interval (T ₂ = τ _2, τ ₂ - symbol transmission duration "0"), separated signal corresponding to the symbol "0", the beginning lo and end of the integration interval T ₂ is combined with the start and "0" symbol transmission end.

The achievement of the technical result is ensured by the application of the integration operation at the receiving point, and the beginning and end of the integration is carried out at characteristic points, which are the times of the transition of the supply voltage U (t) = U _m cosΩt through zero at dU (t) / dt ≥ 0. These time points correspond to the beginning and end of the transmission of the characters "1" and "0" at the transmitting point.

 The drawing shows a functional diagram of a device for receiving and transmitting signals in a three-phase electrical network.

 The device contains a three-phase electric network 1, to which the inputs of the first 2 and second 3 voltage filters of symmetrical components are connected, the outputs of each of which are connected respectively to the inputs of the first 4 and second 5 narrow-band filters, the outputs of each of which are respectively connected to the first and second inputs of the first multiplier 6, the output of which is connected to the first input of the first mixer 7, the output of which is connected to the input of the first low-pass filter 8, the local oscillator 9, the input of which is connected to a three-phase electric ohm network 1, and the output is connected to the second input of the first mixer 7, the first transmitter is a passive-active type 10, the output of which is connected to a three-phase electric network 1, the third 11 and fourth 12 voltage filters of symmetrical components, the inputs of each of which are connected to a three-phase electric network 1, and the outputs are respectively connected to the inputs of the third 13 and fourth 14 narrow-band filters, the outputs of each of which are respectively connected to the first and second inputs of the second multiplier 15, the output of which is connected to the inverter input Ora 16, the output of which is connected to the first input of the second mixer 17, the output of which is connected to the input of the second low-pass filter 18, the second input of the second mixer 17 is connected to the output of the local oscillator 9, the output of the second transmitter of the passive-active type 19 is connected to a three-phase electric network 1, the inputs of the first 20 and second 21 synchronizers are connected to a three-phase electric network 1, the output of the first synchronizer 20 is connected respectively to the first inputs of the first 22 and second 23 integrators, the output of the second synchronizer 21 is connected respectively To the inputs of the first 10 and second 19 transmitters of the passive-active type, the output of the first low-pass filter 8 is connected to the second input of the first integrator 22, the output of the second low-pass filter 18 is connected to the second input of the second integrator 23.

 The device operates as follows.

The output of the local oscillator 9 have a local oscillator voltage
U _g (t) = U _mg cos2Ωt (n = 2),
Where
U _mg - the amplitude value of the voltage of the local oscillator;
Ω = 2πF is the circular frequency;
F is the frequency of industrial voltage.

 Transmit and receive the character "1".

From the output of the first passive-active type transmitter 10, negative sequence currents at a frequency f ₁ and a direct sequence at a frequency f ₂ are introduced into a three-phase electric network 1, the analytical value of which is described by the expressions (Kutin KI Improving the efficiency of information transmission in rural electric networks by voltage 10 kV. Abstract for the degree of Ph.D. MIISP, - M., 1987, p. 7).

,
где
I_m - максимальное значение тока передатчика 10.

,
Where
I _m is the maximum value of the transmitter current 10.

From these relations it follows that the currents at a frequency of ω ₁ have the reverse phase rotation (A, C, B), i.e. the current in phase C is 120 ^o behind the current in phase A, and the current in phase B is 120 ^o behind the current in phase C. At a frequency of ω _{2, there} is a direct phase rotation (A, B, C).

= 2F. Первый фильтр напряжения симметричных составляющих обратной последовательности 2 настроен на частоту f₁, второй фильтр напряжения симметричных составляющих прямой последовательности 3 настроен на частоту f₂. С выходов первого и второго фильтров напряжения симметричных составляющих 2 и 3 напряжения поступают на входы первого и второго узкополосных фильтров 4 и 5. С выходов первого и второго узкополосных фильтров 4 и 5 напряжения частот f₁ и f₂ поступают на входы первого умножителя 6.These currents form a voltage of the negative sequence signal U ₂ (f ₁ ) at a frequency f ₁ and a voltage of a direct sequence signal U ₁ (f ₂ ) at a frequency f ₂ in a three-phase electric network, and

= 2F. The first voltage filter of the symmetrical components of the reverse sequence 2 is tuned to the frequency f ₁ , the second voltage filter of the symmetrical components of the direct sequence 3 is tuned to the frequency f ₂ . From the outputs of the first and second filters, the voltage of the symmetrical components 2 and 3 is supplied to the inputs of the first and second narrow-band filters 4 and 5. From the outputs of the first and second narrow-band filters 4 and 5, the voltage frequencies f ₁ and f ₂ are applied to the inputs of the first multiplier 6.

Let the output voltage of the first narrow-band filter 4 have a signal voltage
U ₄ (t) = U _m4 cos (ω ₁ t + φ ₁ ) (1).

The output of the second narrow-band filter 5 have a signal voltage
U ₅ (t) = U _m5 cos (ω ₂ t + φ ₂ ) (2),
Where
φ ₁ = φ ₂ . (3)
This follows from the principle of operation of the passive-active type transmitter 10. At t ≤ 0. The transmitter 10 at the transmission point does not work. At the reception point there are no voltage signals U ₄ (t) and U ₅ (t) described by expressions (1) and (2).

At t> 0. The transmitter 10 at the transmission point starts to work. At the receiving point, voltages U ₄ (t) and U ₅ (t) appear.

,
где
U_m4, U_m5 - амплитудные значения напряжений сигналов на входах первого умножителя 6;
K - коэффициент передачи.The voltage of the signals U ₄ (t) and U ₅ (t) is supplied to the first and second inputs of the first multiplier 6, from the output of which the voltage of the signal U ₆ (t) is supplied to the first input of the first mixer 7, and

,
Where
U _m4 , U _m5 - amplitude values of the voltage of the signals at the inputs of the first multiplier 6;
K is the gear ratio.

= 2F (7).φ ₆ = (ω ₁ -ω ₂ ) t + φ ₁ -φ ₂ (5),
Where
ω ₁ = 2πf ₁ ; ω ₂ = 2πf ₂ . (6)
Moreover, the condition

= 2F (7).

Taking into account expressions (3) and (6), expression (5) takes the form
φ ₆ = 2π (f ₁ -f ₂ ) t + φ ₁ -φ ₂ = 2Ωt (8).

.In view of (8), expression (4) takes the form
U ₆ (t) = A ₆ cos2Ωt (9),
Where

.

The signal voltage U ₆ (t) is supplied to the first input of the first mixer 7.

The local oscillator voltage 9 U _g (t) = U _mg cos2Ωt is supplied to the second input of the first mixer 7. Thus, two voltages with equal frequencies and phases are supplied to the first and second inputs of the first mixer 7.

,
где
m - постоянный коэффициент, зависящий от амплитуды напряжения гетеродина;
ρ₀ - крутизна характеристики первого смесителя;
A₀ - амплитудное значение.The voltage at the output of the first mixer 7 is determined from the expression

,
Where
m is a constant coefficient depending on the amplitude of the local oscillator voltage;
ρ ₀ - the steepness of the characteristics of the first mixer;
A ₀ is the amplitude value.

An analysis of expression (10) shows that the first and second terms are voltages having frequencies of 2Ω and 4Ω. The last term is a positive constant voltage U ₁ .

Voltage U ₁ corresponds to a positive video pulse in the description of the claims.

The voltage U ₁ acts for a time t, where
0 ≤ t ≤ τ ₁ ,
τ ₁ - the duration of the transmission of the character "1".

.

.

 To highlight the positive DC voltage, which characterizes the reception of the symbol "1", the voltage from the output of the first mixer 7 according to (10) is supplied to the input of the first low-pass filter 8, the output of which has a positive constant voltage according to (11).

The second synchronizer 21 generates video pulses of duration τ ₁ that arrive at the first transmitter 10, and the beginning and end of the video pulse corresponds to the transition of the supply voltage U (t) through zero at dU (t) / dt ≥ 0. Thus, the duration τ ₁ = 0, 02 s (at a frequency of supply voltage F = 50 Hz). These pulses are fed to the input of the transmitter 10, which ensures the transmission of the symbol "1" at strictly fixed times. The first synchronizer 20 generates pulses of the transition of the supply voltage through zero at dU (t) / dt ≥ 0. These pulses zero the first integrator 22 at the beginning and end of the transmission of the symbol “1”, i.e. satisfy the condition T ₁ = τ ₁ .
Transmit and receive the character "0".

From the output of the second passive-active type transmitter 19, negative sequence currents at a frequency f ₃ and a direct sequence at a frequency f ₄ are introduced into a three-phase electric network 1. These currents form in the three-phase electric network 1 voltage signals of the negative sequence U ₂ (f ₃ ) at a frequency f ₃ and a direct sequence U ₁ (f ₄ ). The third filter of symmetrical components of the negative sequence 11 is tuned to the frequency f ₃ , the fourth filter of symmetric components of the direct sequence 12 is tuned to the frequency f ₄ . From the outputs of the third and fourth filters of symmetrical components 11 and 12, the voltages are supplied respectively to the inputs of the third and fourth narrow-band filters 13 and 14. From the outputs of the third and fourth narrow-band filters 13 and 14, voltage frequencies f ₃ and f ₄ are applied to the inputs of the second multiplier 15.

Let the output voltage of the third narrow-band filter 13 have the signal voltage
U ₁₃ (t) = U _m13 cos (ω ₃ t + φ ₃ ) (12).

По аналогии с приемом символа "1" напряжение на выходе второго умножителя 15 будет равно
U₁₅(t) = A₁₅cos 2Ωt,
где

.From the output of the fourth narrow-band filter 14 we have a signal voltage

By analogy with the reception of the symbol "1", the voltage at the output of the second multiplier 15 will be equal to
U ₁₅ (t) = A ₁₅ cos 2Ωt,
Where

.

Comparing expressions (9) and (14), we conclude that they are identical. In order to distinguish the symbol "0" from the symbol "1", the voltage from the output of the second multiplier is supplied to the input of the inverter 16. The voltage at its output will be equal to
U ₁₆ (t) = -A ₁₅ cos 2Ωt (15).

It should be noted that a change in the phase shift of 180 ^o in the expressions (1) and (2), which can be obtained on the transmitting side, does not change sign in the output voltage of the multiplier, because according to (5), adding the same angles to φ ₁ + π and φ ₂ + π will give the angle φ according to expression (8). In this case, the voltage of the local oscillator 9 and the signal voltage at the output of the inverter 16 are shifted by 180 ^o .

The voltage U ₁₆ (t) corresponds to the voltage U ₂ (t) in the description of the claims.

 This voltage is supplied to the first input of the second mixer 17, the second input of which serves the voltage of the local oscillator 9.

.The voltage at the output of the second mixer 17 U ₁₇ (t) by analogy with (10) is determined from the expression

.

.This voltage is applied to the second low-pass filter 18, where a negative voltage is emitted, which characterizes the reception of the symbol "0". The output of the second low-pass filter 18 has a voltage

.

Voltage U ₂ corresponds to a negative video pulse in the description of the claims.

The voltage U ₂ acts for a time t, where
0 ≤ t ≤ τ ₀ ,
τ ₀ - the duration of the transmission of the character "0".

The second synchronizer 21 generates video pulses of duration τ ₀ that arrive at the second transmitter 19.

The durations of the characters "1" and "0" are taken equal, i.e. τ ₁ = τ ₀ = τ = 0.02 s.
The pulses of the first synchronizer 20 are also reset by the second integrator 23 at the moments of the beginning and end of the transmission of the symbol "0".

Таким образом доказано, что предложенное устройство реализует заявленный способ передачи и приема сигналов в трехфазной электрической сети.The signal transmission speed V will be equal to

Thus, it is proved that the proposed device implements the claimed method of transmitting and receiving signals in a three-phase electric network.

Claims (1)

A method of receiving and transmitting signals in a three-phase electric network, in which at the point of transmission, when transmitting the symbol "1", the voltage of the industrial frequency F is converted to a negative sequence current at a frequency f ₁ and a direct sequence current at a frequency f ₂ , these currents are transmitted through a three-phase electric network at the receiving point, characterized in that the following operations are introduced into it: at the receiving point, the currents at frequencies f ₁ and f _{2 are} converted to voltage U ₁ (t) = U _n1 cosnΩt, (n = 1,2,3, ... , n-1, Ω = 2πF), convert the industrial frequency voltage F to hetero voltage dyne U _g (t) = U _m cosnΩt, convert the voltages U ₁ (t) and U _g (t) into a constant positive voltage U ₁ , integrate the voltage U ₁ over the interval T ₁ (T ₁ = τ ₁ , τ ₁ - duration transmitting the symbol "1"), select the signal corresponding to the symbol "1", and the beginning and end of the integration interval T ₁ , as well as the beginning and end of the transmission of the symbol "1" corresponds to the transition points of the voltage of the industrial frequency F at the points of transmission and reception through zero at dU / dt ≥ 0 (U is the voltage of the industrial frequency f), when transmitting the symbol "0" at the transmission point, the voltage of thought frequency F into a reverse sequence current at a frequency f ₃ and a direct sequence current at a frequency f ₄ , transfer these currents through a three-phase electric network to a receiving point, convert currents at frequencies f ₃ and f ₄ to a voltage U ₂ (t) = U _m2 cos (nΩt-180 ^° ), convert voltages U ₂ (t) and U _r (t) into a constant negative voltage U ₂ , integrate voltage U ₂ over the interval T ₂ (T ₂ = τ ₂ , τ ₂ - symbol transmission time " 0 "), separated signal corresponding to the symbol" 0 ", the start and end of the integration interval T _2, as well as the beginning and end of transmission Char la "0" correspond to the moments of transition frequency voltage through zero at F dU / dt ≥ 0.