RU84576U1 - DEVICE FOR DETERMINING CURRENT ELECTRIC TRANSMISSION LINE PARAMETERS - Google Patents

Abstract

A device for determining the current parameters of the power line, containing four sampling-storage devices connected through the communication channel to emergency recorders at the beginning and at the end of the power line, three inverters, two adders, a programmer, a clock generator, and to the first sampling-storage device the first inverter, the first adder, are connected in series; the first adder, the first programmer, is connected to the second sampling-storage device, a clock generator is connected to each sampling-storage device, characterized in that the second programmer, the third programmer, the fourth programmer, the outputs of which are connected to the computer, are connected to the second programmer to the second programmer the fourth programmer is connected, in addition, the fifth, sixth and seventh programmers, the second inverter and the eighth a grammer, the fifth programmer is connected to the first sampling-storage device, the output of which is connected to the seventh programmer, the third and fifth programmers are connected to the first programmer, the eighth programmer is connected to the fifth and sixth programmers, the fourth programmer is connected to the second inverter and eighth programmer, to the first adder the ninth programmer, the tenth programmer, the output of which is connected to the fourth programmer, to the third sampling-storage device of the last the third inverter, the second adder, are connected to the fourth adder, the output of which with

Description

The utility model relates to the field of information processing systems and can be used for functional control and diagnosis of power lines, based on its T-shaped adaptive model, tunable according to current information about the parameters of the electric mode of the line.

A device is known for determining the current parameters of the electric mode of the power line [RF Patent No. 57016, IPC 7, G01R 25/00, publ. 09/27/2006 Bull. No. 27], selected as a prototype, containing three parallel-connected units for calculating the active and reactive resistances of the longitudinal and transverse branches of the T-shaped equivalent circuit of the power line, the inputs of which are connected to the beginning of the power line and through the communication channel to its end, and the outputs of the calculation units connected to a computer, while in two identical calculation units, the first and second sampling and storage devices are connected to the input of the device, and the inverter and adder are connected in series to the first sampling-storage device; an adder, a programmer, a third access-storage device, a fourth access-storage device, a second inverter, a second adder, the output of which is connected to a multiplier to which an integrator is connected in series, a multiplier-divider, the output of which is connected to A computer, in addition, the input of the fifth sample-storage device is connected to the input of the device, and the sixth sample-storage device is connected in series to the output of the fifth sample-storage device, t ety adder whose output is connected to the first multiplier; a clock is connected to each sample-storage device; the inputs of the third and fifth sampling and storage devices are connected to a second multiplier, the output of which is connected to a second integrator, the output of which is connected to a second divider multiplier connected to a computer; at the same time, the third adder and the converter of effective values are connected to the output of the fifth sampling-storage device, the outputs of which are connected to the third multiplier connected to the inputs of the first and second divider multipliers; the third unit for calculating the active and reactive resistances of the transverse branch of the T-shaped equivalent circuit of the power line contains the seventh and eighth sampling and storage devices, the inputs of which are connected to the input of the device; at the same time, the third inverter, the fourth adder are connected in series to the seventh sample-storage device, the fourth adder, the second programmer, the fourth inverter, the fifth adder are connected in series to the eighth sample-storage device, the input of the ninth sample-storage device is connected to the input of the device, to the output of the ninth the sampling and storage devices are connected in series with the fifth adder, the tenth sampling-storage device, the eleventh sampling-storage device, the fifth inverter, the sixth adder, output for which it is connected to the fourth multiplier, to which the third integrator is connected in series, the third multiplier-divider, the output of which is connected to a computer, the inputs of the twelfth and thirteenth sampling and storage devices are connected to the input of the device, the sixth inverter is connected to the output of the twelfth sampling and storage device, the output which is connected with the seventh adder, the seventh adder, the fourteenth sample-storage device, the fifteenth must be connected in series to the output of the thirteenth sample-storage device roystvo sample and hold, the eighth adder, whose output is connected to the fourth multiplier; a second clock is connected to each sample-storage device; the inputs of the tenth and fourteenth sample-storage devices are connected to the fifth multiplier, the output of which is connected to the fourth integrator, the output of which is connected to the fourth multiplier-divider connected to the computer, the eighth adder and the second converter of effective values are also connected to the output of the fourteenth device the outputs of which are connected to the sixth multiplier associated with the inputs of the third and fourth multiplier divisors.

The objective of the utility model is to expand the arsenal of technical means for determining the current parameters of the power line to build its T-shaped adaptive model.

The device for determining the current parameters of the power line contains four sampling-storage devices connected via a communication channel to emergency recorders at the beginning and at the end of the power line, three inverters, two adders, a programmer, and a clock generator. In this case, the first inverter, the first adder, are connected in series to the first sampling-storage device; the first adder, the first programmer, is connected to the second fetch-storage device. A clock is connected to each sample-storage device. According to a utility model, a second programmer, a third programmer, a fourth programmer, the outputs of which are connected to a computer, are connected in series to the first programmer. A fourth programmer is connected to the second programmer. In addition, the fifth, sixth and seventh programmers, the second inverter and the eighth programmer are connected in series to the second sample-storage device. A fifth programmer is connected to the first sample-storage device, the output of which is connected to the seventh programmer. The third and fifth programmers are connected to the first programmer. The eighth programmer is connected to the fifth and sixth programmers. A fourth programmer is connected to the second inverter and the eighth programmer. The ninth programmer, the tenth programmer, the output of which is connected to the fourth programmer are connected in series to the first adder. The third inverter, the second adder, are connected in series to the third sample-storage device. A second adder is connected to the fourth sample-storage device, the output of which is connected to the seventh and eighth programmers. In addition, the eleventh programmer, the twelfth programmer, the output of which is connected to the fourth programmer, are connected in series to the fourth sampling-storage device. Moreover, the thirteenth programmer is connected to the third sample-storage device, the output of which is connected to the second and third programmers. In addition, the second and third programmers are connected to the third sample-storage device. The fifth and twelfth programmers are connected to the ninth programmer. The tenth and twelfth programmers are connected to the fourth sample-storage device. The tenth programmer is connected to the eleventh and twelfth programmers.

Using the proposed device circuit, you can determine the current parameters of the T-shaped equivalent circuit of the power line (figure 3):

1) the active resistance R ^' _1i , R ^” _1i and inductance L ^' _1i , L ^” _{1i of the} longitudinal branches of the line;

2) resistance R _0i and capacitance C _0i , the transverse branch of the line.

Figure 1 presents the structural diagram of the inclusion of a device for determining the current parameters of the power line in the power line and to the system (computer).

Figure 2 shows the hardware circuit of the device for determining the current parameters of the line.

Figure 3 presents the T-shaped equivalent circuit of the power line.

The device (figure 1) for determining the current parameters of the power line 1 contains a unit 2 for calculating R ^' _1cp , L ^' _1cp , R ^” _1cp , L ^” _1cp , R _0cp , C _0cp whose inputs are connected through the communication channel (CS) to emergency recorders situations at the beginning and at the end of the power line (not shown in figure 1), and the outputs of the calculation unit 2 are connected to the computer 3.

Calculation block 2 (FIG. 2) consists of the first 4 (UVX 1), second 5 (UVX 2), third 6 (UVX 3) and fourth 7 (UVX 4) sampling and storage devices, the inputs of which are connected to emergency recorders. The first inverter 8, the first adder 9 are connected in series to the first sampling-storage device 4 (UVX 1). The first adder 9, the first programmer 10 (P 1), and the second programmer 11 are connected in series to the second sampling-storage device 5 (UVX 1) P 2), the third programmer 12 (P 3), the fourth programmer 13 (P 4), the outputs of which are connected to the computer 3. The second programmer 13 (P 4) is connected to the second programmer 11 (P 2). In addition, the fifth 14 (P 5), sixth 15 (P 6) and seventh 16 (P 7) programmers, the second inverter 17 and the eighth programmer 18 (P 8) are connected in series to the second sampling-storage device 5 (UVX 2). The fifth programmer 14 (P 5) is connected to the first sampling-storage device 4 (UVX 1), the output of which is connected to the seventh programmer 16 (P 7). The third 12 (P 3) and fifth 14 (P 5) programmers are connected to the first programmer 10 (P 1). To the fifth 14 (P 5) and sixth 15 (P 6) programmers the eighth programmer 18 (P 8) is connected. The outputs of the second inverter 17 and the eighth programmer 18 (P 8) are connected to the fourth programmer 13 (P 4). The ninth programmer 19 (P 9), the tenth programmer 20 (P 10), the output of which is connected to the fourth programmer 13 (P 4), are connected to the first adder 9 in series. The third inverter 21, the second adder 22 are connected in series to the third sampling-storage device 6 (UVX 3). The second adder 22 is connected to the fourth sampling-storage device 7 (UVX 4), the output of which is connected to the seventh 16 (P 7) and the eighth 18 (P 8) programmers. In addition, the eleventh programmer 23 (P 11), the twelfth programmer 24 (P 12), the output of which is connected to the fourth programmer 13 (P 4), are connected in series to the fourth sampling-storage device 7 (UVX 4). Moreover, the thirteenth programmer 25 (P 13), the output of which is connected to the second 11 (P 2) and third 12 (P 3) programmers, is connected to the third sampling-storage device 6 (UVX 3). In addition, the second 11 (P 2) and third 12 (P 3) programmers are connected to the third sampling-storage device 6 (UVX 3). The fifth programmer 19 (P 9) is connected to the fifth 14 (P 5) and twelfth 24 (P 12) programmers. The output of the fourth sampling-storage device 7 (UVX 4) is associated with the tenth 20 (P 10) and twelfth 24 (P 12) programmers. The inputs of the tenth programmer 20 (P 10) are connected to the eleventh 23 (P 11) and twelfth 24 (P 12) programmers. A clock generator 26 (TG) is connected to each sample-storage device.

All sampling and storage devices are implemented on 1100SK2 microcircuits. The programmers are made on a microcontroller series 51 manufacturer atmel AT89S53. Inverters and combiners are implemented on operational amplifiers 140UD17A. The clock generator 26 (TG) can be implemented on the AT80C2051 microcontroller.

The device operates as follows. In the load mode, the inputs of the calculation unit 2 R ^' _1cp , L ^' _1cp , R ^” _1cp , L ^” _1cp , R _0cp , C _0cp , devices from emergency recorders simultaneously give signals to the input buses of unit 2 of calculation R ' _1cp , L' _1cp , R ” _1cp , L” _1cp , R _0cp , C _0cp , where - an array of samples of instantaneous voltage values at the beginning of the power line,

- an array of samples of instantaneous current values at the beginning of power lines,

- an array of samples of instantaneous voltage values at the end of the line,

- an array of samples of instantaneous current values at the end of the power line.

At block 2 of the calculation of R ^' _1cp , L ^' _1cp , R ^” _1cp , L ^” _1cp , R _0cp , C _0cp to the input of the first sampling-storage device 4 (UHF 1) receives a signal u ₂ (t _j ), to the input of the second device sampling-storage 5 (UVX 2) signal u ₁ (t _j ), and to the input of the third sampling-storage device 6 (UVX 3) signal i ₂ (t _j ), and to the input of the fourth sampling-storage device 7 (UVX 4) signal i ₁ (t _j ),

where t _j = t ₁ , t ₂ , ..., t _N - time instants,

N = T / Δt is the number of partitions on the period T,

Δt = 0.625 ∙ 10 ^-3 s is the sampling step of the arrays of instantaneous current / voltage values at the beginning and at the end of power lines.

The values of the signals are recorded in the sampling-storage device 4 (UVX 1), 5 (UVX 2), 6 (UVX 3) and 7 (UVX 4) and stored there as current ones, then from the output of the first sampling-storage device 4 (UVX 1) ) the signal u ₂ (t _j ) enters the fifth programmer 14 (P 5) and the first inverter 8, with which the negative value of the previous signal u ₂ (t _j ) is converted to positive. From the output of the first inverter 8, the signal value u ₂ (t _j ) is fed to the input of the first adder 9. At the same time, from the output of the second sampling-storage device 5 (UX2), the signal value u ₁ (t _j ) is fed to the second input of the first adder 9 and the fifth programmer 14 (P 5). Using the first adder 9 determine the difference in the values of the signals u ₁ (t _j ) -u ₂ (t _j ). From the output of the adder 9, the difference in the values of the signals u ₁ (t _j ) -u ₂ (t _j ) enters the programmers 10 (P 1) and 19 (P 9). At the same time, the value of the signal i ₂ (t _j ) enters the third sampling-storage device 6 (UVX 3), and the value of the signal i ₁ (t _j ) enters the fourth sampling-storage device 7 (UVX 4). The values of the signals recorded in the sample-storage device 6 (UVX 3) and 7 (UVX 4) are stored there as current. Then, from the output of the third sampling-storage device 6 (UVX 3), the signal i ₂ (t _j ) enters the programmers 11 (P 2), 12 (P 3), 25 (P 13) and to the third inverter 21, with the help of which it is negative the value of the previous signal i ₂ (t _j ) is converted to positive. From the output of the third inverter 21, the value of the signal i ₂ (t _j ) is fed to the input of the second adder 22. At the same time, from the output of the fourth sampling-storage device 7 (UVX 4), the value of the signal i ₁ (t _j ) is fed to the programmers 20 (P 10), 23 (P 11), 24 (P 12) and to the second input of the second adder 22, with which the difference in the values of the signals i ₁ (t _j ) -i ₂ (t _j ) is determined. From the output of the second adder 22, the difference in the values of the signals i ₁ (t _j ) -i ₂ (t _j ) enters the seventh 16 (P 7) and eighth 18 (P 8) programmers. Using the first programmer 10 (P 1), the difference in the values of the signals u ₁ (t _j ) -u ₂ (t _j ) is changed proportionally to the coefficient (1-k), and k = 0; 0,1 ... 1. From the output of the first programmer 10 (P 1), the signal Δu ” ₁₂ (t _j ) = (1-k) · Δu ₁₂ (t _j ) enters the programmers 11 (P 2), 12 (P 3) and 14 (P 5) . At the same time, using the ninth programmer 19 (P 9), the difference in the values of the signals u ₁ (t _j ) -u ₂ (t _j ) is changed proportionally to k, and the coefficient k = 0; 0,1 ... 1. From the output of the ninth programmer 19 (P 9) signal enters the programmers 14 (P 5), 20 (P 10) and 24 (P 12). At the same time, using the eleventh programmer 23 (P 11) determine the values of the derivatives of the signal and :

From the output of the eleventh programmer 23 (P 11) the values of the derivatives of the signal and arrive at the inputs of the tenth 20 (P 10) and twelfth 24 (P 12) programmers. At the same time using the thirteenth programmer 25 (P 14) determine the values of the derivatives of the signal and :

From the outputs of the thirteenth programmer 25 (P 14) the values of the derivatives of the signal and arrive at the inputs of the second 11 (P 2) and third 12 (P 3) programmers. Using programmer 14, the fifth (Q 5) is determined or the difference values of the signals u ₀ (t _j) = u ₁ (t _j) -Δu _'12 (t _j) or the sum of values of the signals u ₀ (t _j) = u ₂ (t _j ) -Δu ” ₁₂ (t _j ). From the output of the fifth programmer 14 (P 5), the signal u ₀ (t _j ) enters the sixth 15 (P 6), seventh 16 (P 7) and eighth 18 (P 8) programmers. Using the sixth programmer 15 (P 6) determine the values of the derivatives of the signal and :

From the output of the sixth programmer 15 (P 6) the values of the derivatives of the signal and the seventh 16 (P 7) and eighth 18 (P 8) programmers arrive. Using the twelfth programmer 24 (P 12) determine the value of the inductance longitudinal branches of the power line (figure 3):

From the output of the twelfth programmer 24 (P 12) the inductance value the longitudinal branch of the power line goes to the inputs of the fourth 13 (P 4) and tenth 20 (P 10) programmers. At the same time using the second programmer 11 (P 2) determine the inductance value longitudinal branches of the power line (figure 3):

From the output of the second programmer 11 (P 2) the inductance value the longitudinal branch of the power line goes to the inputs of the third 12 (P 3) and fourth 13 (P 4) programmers. At the same time, using the seventh programmer 16 (P 7) determine the value of the capacitance C _0i , the transverse branch of the power line (figure 3):

From the output of the seventh programmer 16 (P 7), the value of the capacitance C _0i , the transverse branch of the power line to the inputs of the fourth programmer 13 (P 4) and the second inverter 17, with which a negative value of the capacitance C _0i , is converted to positive. From the output of the second inverter 17, the value of capacitance C _0i , is fed to the input of the eighth programmer 18 (P 8). Using the tenth programmer 20 (P 10) determine the inductance value longitudinal branches of the power line (figure 3):

From the output of the tenth programmer 20 (P 10) the value of the active resistance the longitudinal branch of the power line is fed to the input of the fourth programmer 13 (P 4). At the same time using the third programmer 12 (P 3) determine the value of the active resistance longitudinal branches of the power line (figure 3):

From the output of the third programmer 12 (P 3) the value of the active resistance the longitudinal branch of the power line is fed to the input of the fourth programmer 13 (P 4). At the same time, using the eighth programmer 18 (P 8) determine the value of the active resistance R _0i , the transverse branch of the power line (figure 3):

From the output of the eighth programmer 18 (P 8), the resistance value R _{0i of the} transverse branch of the power line is fed to the input of the fourth programmer 13 (P 4). Using the fourth programmer 13 (P 4), the average values for the period of active resistance and inductance of the longitudinal branches, active resistance and capacitance of the transverse branch of the power line are determined by the formulas:

,

Where , , , , , - accordingly, the number of values , , , , , found on the period.

In idle mode, the operation of block 2 calculation , , , , , similar to work in load mode, with the coefficient k = 1.

When working block 2 calculation , , , , , retain pairs of digital samples of voltage and current as the current is determined signal difference values u ₁ (t _j) -u ₂ (t _j) and i ₁ (t _j) -i ₂ (t _j), alter the difference signal values Δu _'12 ( t _j ) = k · Δu ₁₂ (t _j ) and Δu ” ₁₂ (t _j ) = (1-k) · Δu ₁₂ (t _j ) in proportion to the coefficient k = 1. At the same time, the derivatives of the signal are determined and :

At the same time, the derivatives of the signal are determined and :

Next define or difference values of the signals u ₀ (t _j) = u ₁ (t _j) -Δu _^'12 (t _j) or the sum signal values u ₀ (t _j) = u ₂ (t _j) + Δu _^"12 (t _j ). Derivate Signal Derivatives and :

Then determine the value of the inductance longitudinal branches of the power line (figure 3):

At the same time, the inductance value is determined. longitudinal branches of the power line (figure 3):

At the same time, the value of the capacitance C _{0i of the} transverse branch of the power line is determined (FIG. 3):

Next, determine the value of active resistance longitudinal branches of the power line:

At the same time, the resistance value is determined longitudinal branches of the power line (figure 3):

At the same time, determine the value of the active resistance R _{0i of the} transverse branch of the power line (figure 3):

Then, the average values for the period of the active resistances and inductances of the longitudinal branches, the active resistance and the capacitance of the transverse branch of the power line are determined by the formulas:

Where , , , , , - accordingly, the number of values , , , , , found on the period.

Thus, the utility model allows to measure the resistance , and inductance , longitudinal branches, active resistance , and capacity the transverse branch of the T-shaped equivalent circuit of the power line.

Claims (1)

A device for determining the current parameters of the power line, containing four sampling-storage devices connected through the communication channel to emergency recorders at the beginning and at the end of the power line, three inverters, two adders, a programmer, a clock generator, and to the first sampling-storage device the first inverter, the first adder, are connected in series; the first adder, the first programmer, is connected to the second sampling-storage device, a clock generator is connected to each sampling-storage device, characterized in that the second programmer, the third programmer, the fourth programmer, the outputs of which are connected to the computer, are connected to the second programmer to the second programmer the fourth programmer is connected, in addition, the fifth, sixth and seventh programmers, the second inverter and the eighth a grammer, the fifth programmer is connected to the first sampling-storage device, the output of which is connected to the seventh programmer, the third and fifth programmers are connected to the first programmer, the eighth programmer is connected to the fifth and sixth programmers, the fourth programmer is connected to the second inverter and eighth programmer, to the first adder the ninth programmer, the tenth programmer, the output of which is connected to the fourth programmer, to the third sampling-storage device of the last the third inverter, the second adder are connected, the second adder is connected to the fourth sampling-storage device, the output of which is connected to the seventh and eighth programmers, in addition, the eleventh programmer and the twelfth programmer whose output is connected to the fourth programmer are connected in series to the fourth sampling-storage device moreover, the thirteenth programmer is connected to the third sample-storage device, the output of which is connected to the second and third programmers, in addition, to the third oystvu sampling-storage connected second and third programmer, the programmer coupled to the fifth to the ninth and twelfth programmers, the fourth sample and hold device connected to the tenth and twelfth programmers, the eleventh and twelfth tenth programmer connected programmer.