RU189717U1 - DEVICE FOR MEASURING THE FREQUENCY OF THREE-PHASE SINUSOIDAL VOLTAGE - Google Patents

Abstract

The utility model relates to the field of measuring electrical energy parameters and can be used in devices measuring the frequency of a three-phase alternating voltage or current, as well as in devices for automation and relay protection. The device contains a differentiator, a separating device, a peak detector, a module extraction unit, three controlled voltage limiters, the first inputs of which are connected respectively to three phase three-phase voltage wires, an adder, a scaler and a low-pass filter, the output of the differentiator connected to the first input of the separating device, the output of which is connected to the input of the module allocation unit, the second input of the separating device is connected to the output of the peak detector, the input of which is connected to the first ф the three-phase voltage wire, the outputs of the controlled voltage limiters are connected to the corresponding inputs of the adder, the output of which is connected to the differentiator input, the output of the peak detector is connected to the input of the scaling unit, the output of which is connected to the second inputs of the controlled voltage limiters, and the output of the selection module of the module is connected to the filter input low frequency output of which is the output of the device. The technical result in the implementation of the claimed solution is to improve the accuracy frequency of rhenium. 2 Il.

Description

The invention relates to the field of measuring electrical energy parameters and can be used in devices measuring the frequency of a three-phase alternating voltage or current, as well as in devices for automation and relay protection.

Known frequency meter [USSR Author's Certificate No. 458774 IPC ⁸ G01R23 / 00, publ. 01/30/1975], containing a series-connected amplifier-limiter, a metering capacitor and a diode splitter formed by two diodes, a differential DC amplifier with a parallel RC circuit in the feedback circuit and an indicator.

The disadvantage of this device is that the time constant of the RC low-pass filter circuit is chosen sufficiently large on the basis of a given value of the ripple of the output voltage at the lowest operating frequency. Therefore, in a wide range of changes in the frequency of the input signal, the device has a low speed.

The closest analogue to the proposed utility model is a device for measuring the frequency of a three-phase sinusoidal voltage [USSR Author's Certificate No. 577469 IPC ⁸ G01R23 / 02, publ. 10.25.1977], containing a three-input comparator, a decoder, a key block, a peak detector, a module extraction block, a series-connected differentiator and a separating device, the comparator inputs connected to the inputs of the three-phase voltage phases and three outputs of the comparator through the decoder connected to the control input of the key block, the combined output of which is connected to the input of the differentiator, while the input of the peak detector is connected to the first input of the three-input comparator, and the output The peak detector is connected to the first input of the dividing device, the output of which is connected to the input of the module allocation unit.

This technical solution is selected as a prototype.

The disadvantage of this device is the low accuracy of frequency measurement, due to the large number of conversions of input signals and ripple output voltage. In addition, the non-ideal and non-identical keys in the key block leads to the appearance of additional low-frequency ripples in the output voltage, which requires a reduction in the cut-off frequency of the output low-pass filter, designed to smooth the ripple. This leads to a decrease in device performance and an additional decrease in the accuracy of frequency measurement in transient conditions.

The technical result of the claimed utility model is to improve the accuracy of frequency measurement.

This technical result is achieved in that a known device for measuring the frequency of a three-phase sinusoidal voltage, comprising a differentiator, a separating device, a peak detector and a module allocation unit, the output of the differentiator connected to the first input of the separating device, the output of which is connected to the module allocation unit the second input of the divider device is connected to the output of the peak detector, the input of which is connected to the first phase wire of the three-phase voltage, additionally The first, second, and third controlled voltage limiters, the first inputs of which are connected respectively to the first, second, and third phase wires of the three-phase voltage, an adder, a scaling unit, and a low-pass filter, and the outputs of the controlled voltage limiters are connected to the corresponding inputs of the adder, the output of which is connected to input of the differentiator, the output of the peak detector is connected to the input of the scaling unit, the output of which is connected to the second inputs of the controlled voltage limiters, and The output of the module allocation unit is connected to the input of a low-pass filter, the output of which is the output of the device.

The essential differences of the proposed device is the introduction of an additional three controlled voltage limiters, an adder, a scaling unit, a low-pass filter and the organization of new connections between the elements of the device. The combination of elements and relations between them ensures the achievement of a positive effect - improving the accuracy of frequency measurement.

The essence of the utility model is illustrated by drawings. FIG. 1 shows a functional diagram of the device; FIG. 2 - time diagrams of voltages u _f , u ₁ -u ₅ , u ₇ and u _out .

A device for measuring the frequency of a three-phase sinusoidal voltage (Fig. 1) contains controlled voltage limiters 1, 2, 3, adder 4, peak detector 5, scaling unit 6, differentiator 7, separating device 8, module allocation unit 9 and low-pass filter 10.

The device works as follows. The first inputs of the controlled voltage limiters 1, 2, 3 receive, respectively, the voltages u _A , u _B , u _C , which are proportional to the phase voltages of the network (Fig. 2):

- амплитуда фазного напряжения;Where

- amplitude of phase voltage;

ω is the circular frequency of the phase voltage.

подающегося на их вторые входы, и на их выходах формируются соответственно напряжения u₁, u₂, u₃. Уровень напряжения ограничения

формируется при помощью пикового детектора 5, измеряющего амплитуду фазного напряжения

и блока масштабирования 6, имеющего коэффициент передачи 0,5.Controlled voltage limiters 1, 2, 3 limit the voltages u _A , u _B , u _C at the voltage level

served on their second inputs, and their outputs are formed, respectively, the voltage u ₁ , u ₂ , u ₃ . Voltage level limits

formed by using a peak detector 5, measuring the amplitude of the phase voltage

and a scaling unit 6 having a transmission coefficient of 0.5.

Output voltages u ₁ , u ₂ , u _{3 of} controlled voltage limiters 1, 2, 3 are fed to the inputs of adder 4, at the output of which, after the summing operation, an alternating voltage u _{4 is formed} , which has a form close to triangular (Fig. 2).

вырабатываемого пиковым детектором 5 (фиг. 2).As a result of differentiation of voltage u ₄ by the differentiator 7, an alternating voltage u ₅ is formed at its output, which is close to rectangular in shape. To eliminate the influence of the magnitude of the phase voltage on the measured frequency, in the dividing device 8, the output voltage u _{5 of the} differentiator 7 is divided by the amplitude of the phase voltage

produced by the peak detector 5 (Fig. 2).

After rectification of the alternating voltage u ₆ in the block selection module 9, a constant voltage u ₇ is formed at its output, containing minor ripples that are effectively smoothed by the low-pass filter 10 having a small time constant.

As a result, at the output of the low-pass filter 10 and at the output of the device, a constant voltage u _{out is formed} , which does not contain a variable component, and its value is proportional to the measured frequency from the three-phase sinusoidal mains voltage.

Thus, in the proposed utility model, the number of signal transforms is significantly reduced, and, consequently, the accuracy of the frequency measurement is increased.

In the practical implementation of the proposed device, controlled voltage limiters 1, 2, 3 can be performed according to the scheme of limiters on an operational amplifier (OU) (A. J. Peyton, V. Volsh. Analog electronics on operational amplifiers. - M .: BINOM, 1994, p. 225, Fig. 11.8, a). Adder 4 is a conventional three-input adder at the OS. Peak detector 5 can be performed by one of the known schemes (A. J. Peyton, V. Volsh. Analog electronics on operational amplifiers. - M .: BINOM, 1994, p. 292, fig. 11.17; p. 304, fig. 11.29 ). The scaling unit 6 is made in the form of an amplifier at an op-amp with a transfer coefficient of 0.5. Differentiator 7 can be performed according to a well-known scheme on an op-amp with a timing RC circuit. The separating device 8 can be performed at the OS, by including a voltage multiplier on the K525PSZ microcircuit in its negative feedback circuit. As a block allocation module 9, you can use a full-wave rectifier circuit at an op amp, made according to the scheme (A. J. Peyton, V. Volsh. Analog electronics on operational amplifiers. - M .: BINOM, 1994, p. 315, fig. 11.37) . The low-pass filter 10 can be performed according to the first-order low-pass filter scheme at the shelter (A. J. Peyton, V. Volsh. Analog electronics on operational amplifiers. - M .: BINOM, 1994, p. 105, fig. 6.10).

Claims (1)

A device for measuring the frequency of a three-phase sinusoidal voltage, comprising a differentiator, a separating device, a peak detector and a module extraction unit, the output of the differentiator is connected to the first input of a separating device, the output of which is connected to the input of a module allocation unit, and the second input of the separating device is connected to the output of a peak detector The input of which is connected to the first phase wire of the three-phase voltage, characterized in that it additionally introduces the first, second and third controllable Voltage limiters, the first inputs of which are connected respectively to the first, second and third phase wires of the three-phase voltage, an adder, a scaling unit and a low-pass filter, the outputs of the controlled voltage limiters connected to the corresponding inputs of the adder, the output of which is connected to the differentiator, the output of the peak detector connected to the input of the scaling unit, the output of which is connected to the second inputs of the controlled voltage limiters, and the output of the module allocation unit connected with the input of the low-pass filter, the output of which is the output of the device.

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