RU60735U1 - DEVICE FOR FUNCTIONAL CONTROL OF RADIAL THREE-PHASE LINES OF ELECTRIC TRANSMISSIONS WITH ONE-SIDED POWER SUPPLY - Google Patents

Abstract

The utility model relates to the field of electromechanics, namely to the use of information processing tools in electromechanics, and can be used for functional control of radial three-phase power lines with one-way power supply. The objective of the utility model is to create a device for radial three-phase power lines with one-way power in the operating mode. This object is achieved in that the device for functional control of static and dynamic elements of three-phase electrical and electromechanical systems contains an analog-to-digital converter, the inputs of which are connected to current and voltage transformers, and its outputs are connected to the programmer and the ring memory block, the outputs of which are connected to the inputs a programmer whose outputs are connected to the inputs of the comparison unit and to the inputs of the segment indicators, while the outputs of the programmer are connected to the inputs of the memory window of the current values of the phase shifts, the outputs of which are connected to the inputs of the switching unit, and the input unit for admissible differences of the phase shifts, the memory unit and the comparison unit are connected in series, and the inputs of the comparison unit are connected to the outputs of the memory unit of the nominal values of the phase shifts, and the outputs of the comparison unit are connected with the inputs of segment indicators and with the inputs of the switching unit, the outputs of which are connected to the inputs of the memory unit of the nominal values of the phase shifts. 1 ill.

Description

The utility model relates to the field of electromechanics, namely to the use of information processing tools in electromechanics, and can be used for functional control of radial three-phase power lines with one-way power supply.

No analogues are currently known.

The objective of the utility model is to create a device for the functional control of radial three-phase power lines with one-way power in the operating mode.

The problem is achieved in that the device for the functional control of radial three-phase power lines with one-way power supply contains an analog-to-digital converter, the inputs of which are connected to current and voltage transformers, and its outputs are connected to a ring memory block and a programmer. The outputs of the ring memory are connected to the inputs of the programmer, the outputs of which are connected to the inputs of the comparison unit and to the inputs of the segment indicators.

Also, the outputs of the programmer are connected to the inputs of the memory unit of the current values of the phase shifts, the outputs of which are connected to the inputs of the switching unit.

The input unit of permissible differences of phase shifts, the memory unit and the comparison unit are connected in series. Also, the inputs of the comparison unit are connected with the outputs of the memory unit of the nominal values of the phase shifts.

The outputs of the comparison unit are connected to the inputs of the segment indicators and to the inputs of the switching unit.

The outputs of the switching unit are connected to the inputs of the memory unit of the nominal values of the phase shifts.

Thanks to the proposed device designs, it became possible to perform functional control of radial three-phase power lines with one-way power supply.

Figure 1 - presents a functional block diagram of a device for functional control of radial three-phase power lines with one-way power supply.

The proposed device can be implemented, for example, using a functional block diagram, which is presented in figure 1. It contains: analog-to-digital converter 1 (ADC); ring memory unit 2 (KP); programmer

calculation of diagnostic coefficients 3 (P); comparison unit 4 (BS); block input permissible differences of phase shifts 5 (input block); a memory unit 6 (BP), a memory unit for the current values of phase shifts 7 (FFT), a switching unit 8 (BC), a memory unit for nominal values of phase shifts 9 (FFT).

To the inputs of the analog-to-digital Converter 1 (ADC) are connected transformers of current and voltage (not shown in figure 1). The outputs of the converter 1 (ADC) are connected to the inputs of the ring memory block 2 (KP) and to the inputs of the programmer 3 (P). The outputs of the ring memory block 2 (KP) are connected to the inputs of the programmer 3 (P). The outputs of the programmer 3 (P) are connected to the inputs of the comparison unit 4 (BS), to the inputs of the memory unit of the current values of phase shifts 7 (FFT) and to the inputs of the segment indicators (not shown in FIG. 1). Also, the inputs of the comparison unit 4 (BS) are connected to the outputs of the memory unit 6 (BP) and to the outputs of the memory unit of the nominal values of the phase shifts 9 (FFT). The outputs of the comparison unit 4 (BS) are connected to the inputs of the segment indicators (not shown in FIG. 1) and to the inputs of the switching unit 8 (BC). The outputs of the input unit allowable differences of phase shifts 5 (input unit) are connected to the inputs of the memory unit 6 (PSU). Also, the inputs of the switching unit 8 (BC) are connected to the outputs of the memory unit of the current values of the phase shifts 7 (FFT). The outputs of the switching unit 8 (BC) are connected to the inputs of the memory unit of the nominal values of the phase shifts 9 (FFT).

As an analog-to-digital converter 1 (ADC), for example, an analog-to-digital converter of the MAX 186 series (12 bits) can be selected. Ring memory block 2 (KP), memory block 6 (BP), memory block for the current values of phase shifts 7 (FFT), memory block for nominal values of phase shifts 9 (FFT) can be implemented on an external rewritable data memory Amtel AT25L256 (32 kBytes) . Programmer 3 (P) can be executed on the Atmel AT89S53 series 51 microcontroller. The switching unit 8 (BC) can be performed on the basis of the K155TV1 chip.

Upon receipt of the analog signals of currents and voltages of three phases from current and voltage transformers (not shown in Fig. 1) to the input of the analog-to-digital converter 1 (ADC), they are converted into a digital signal with the number N of discrete values of the output signal of the analog-to-digital converter input signal period. Digitized signals of currents i _A (t _j ), i _B (t _j ), i _C (t _j ) and voltages u _A (t _j ), u _B (t _j ), u _C (t _j ), measured at time t _j , arrive simultaneously at the input of the ring memory block 2 (KP) and at the input of the programmer 3 (P). In the block of ring memory 2 (KP), the current values of currents i _A (t _j ), i _B (t _j ), i _C (t _j ) and voltages are stored

u _A (t _j ), u _B (t _j ), u _C (t _j ) to use them at a subsequent point in time. From the outputs of the block of ring memory 2 (KP), the signals i _A (t _j-1 ), i _B (t _j-1 ), i _C (t _j-1 ) and u _A (t _j-1 ), u _B (t _j-1 ), u _C (t _j-1 ), corresponding to the time t _j-1 , are fed to the input of programmer 3 (P). At the same time, the signals of the currents from the outputs of the analog-to-digital converter 1 (ADC) are received at the corresponding inputs of the programmer 3 (P). In programmer 3 (P), the following expressions are used to calculate the phase shifts:

From the outputs of the programmer 3 (P), the signal is fed to the inputs of the comparison unit 4 (BS), to the inputs of the memory unit of the current values of phase shifts 7 (FFT) and to the corresponding inputs of the segment indicators (not shown in figure 1). From the outputs of the memory unit of the current values of phase shifts 7 (FFT), the signal is fed to the inputs of the switching unit. If the outputs of the comparison unit 4 (BS) to the inputs of the switching unit 8 (BC) receives an enable signal recording the current value as the angle of the normal mode, the signal comes from the outputs of the switching unit 8 (BC) to the corresponding inputs of the memory unit of the nominal values of the phase shifts 9 (FFT).

If the inhibit signal is input from the outputs of comparison 4 (BS) to the inputs of switching unit 8 (BC), then as the nominal value of the phase shifts, the signal from the outputs of the memory unit of the nominal values of phase shifts 9 (FFT) is supplied to the inputs of the comparison unit 4 (BS).

The signal from the outputs of the memory unit of the nominal values of the phase shifts 9 (FFT) are fed to the inputs of the comparison unit 4 (BS), where according to the ratios

where Δφ _f are the values of the difference in phase shifts between currents and voltages of the normal and current modes for one of the phases;

- the value of the phase shift between the current and the voltage of the normal mode of one of the phases;

Δφ _Ф values are calculated and compared with allowable values . At the setup stage, using the input unit for permissible phase difference differences 5 (Input unit), the allowable values of the phase differences between currents and voltages are determined based on statistical data for the controlled object. From it, the signal goes to the input of memory unit 6 (PSU), from the outputs of which the signal goes to the inputs of the comparison unit 4 (BS).

Also, from the outputs of the comparison unit 4 (BS), the signal about the serviceability or malfunction of the controlled three-phase system and the phase shifts for each phase are fed to the corresponding inputs of the segment indicators (not shown in Fig. 1).

Based on statistics on ratios

Where , , - values of phase shifts between currents and voltages of emergency mode.

calculate values which, using the input unit allowable differences of phase shifts 5 (input unit) is entered into the memory unit 6 (PSU). Also, based on the operation of the comparison unit, in the memory unit of the nominal values of the phase shifts 9 (FFT) is the value of the phase shifts corresponding to the normal operation of the controlled object.

The serviceability of the power line for each phase is evaluated on the condition that the difference between the current value of the phase shifts and the values for normal operation for one of the phases is less than or equal to their allowable difference .

Current values placed in the memory unit of the current values of the phase shifts 7 (FFT).

Claims (1)

A device for the functional control of radial three-phase power lines with one-way power supply, characterized in that it contains an analog-to-digital converter, the inputs of which are connected to current and voltage transformers, and its outputs are connected to the programmer and the ring memory block, the outputs of which are connected to the inputs of the programmer, outputs which are connected to the inputs of the comparison unit and the inputs of the segment indicators, while the outputs of the programmer are connected to the inputs of the memory unit of the current values of the phase shift s, the outputs of which are connected to the inputs of the switching unit, and the input unit for the permissible differences of the phase shifts, the memory unit and the comparison unit are connected in series, the inputs of the comparison unit being connected to the outputs of the memory unit of the nominal values of the phase shifts, and the outputs of the comparison unit are connected to the inputs of the segment indicators and with the inputs of the switching unit, the outputs of which are connected to the inputs of the memory unit of the nominal values of the phase shifts.