RU2368050C1 - Method of monitoring phase loss in three-phase network and device to this end - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: proposed method of monitoring phase loss in a three-phase network and device for realising the method relate to electrical engineering and are used in circuits of automatic protective devices. The method is based on determining instantaneous values of line voltage as a difference of instantaneous values of phase voltage, measured relative a formed neutral point. The monitored three-phase voltage is stepped down, rectified, smoothed out, and a given voltage level is formed. Voltage across the neutral point is stepped up to a given level relative the common point of the circuit and the period of the phase voltage is determined from transitions through the given level. Phase loss is determined from the value of asymmetry coefficient, calculated as a ratio of root-mean-square values of reverse and forward sequence voltage, using root-mean-square values of line voltage. The device is realised by a device which has leads for connection to a voltage source, a three-phase rectifier, smoothing capacitor, resistors, operational amplifiers, capacitors, ADC and a processor.

EFFECT: highly reliable protection of three-phase equipment.

3 cl, 7 dwg

Description

The present invention relates to electrical engineering and automation, in particular to protective methods and devices, and can be used in electrical circuits of relay protection and emergency automation of electrical installations in three-phase networks.

A device is known [patent RU No. 2033621, IPC G01R 29/18] for automatic and simultaneous control of the correct alternation, phase failure and voltage level in three-phase networks, the device comprising a driver made of three voltage dividers, three rectifier bridges, three level setting potentiometers voltage and three optocoupler switches, three RS-flip-flops and a logic unit.

The disadvantages of the known device is the limited reliability in operation, because the presence of potentiometers in each phase makes it difficult to coordinate the settings of the voltage, the optocouplers have significant technological variations, depending on changes in ambient temperature.

Closest to the proposed invention by technical essence is a method for detecting phase failure and a device for its implementation [US patent No. 2006186892, IPC G01R 29/16, H02H 3/24].

This method of detecting phase failure is to determine the instantaneous values of linear voltages as the difference between the instantaneous values of phase voltages measured relative to the formed neutral point by forming a low-voltage analogue of a controlled three-phase network voltage, rectifying it and smoothing it. Next, the phase shift and the sign of the instantaneous linear stresses are calculated, and in the presence of different signs of two of the three instantaneous linear stresses and a phase shift of 180 °, phase failure is detected.

A device for implementing this method contains inputs for connecting to a three-phase voltage source, a three-phase rectifier, to the outputs of which a smoothing capacitor is connected, resistors, some of whose outputs are connected in phase with the inputs, and others are connected in phase with the outputs of the following resistors, other outputs of which are connected to each other and form a neutral point, operational amplifiers, inputs connected in phase with common points of resistors, and outputs in phase with inputs of analog-to-digital converters (ADC), soy dinned by its outputs with a processor.

The known method and the device that implements it do not determine the phase loss at the input of the step-down transformer connected between the voltage source and the device. When the transformer windings are connected according to the "star - star with a zero wire" circuit and the transformer operates at rated motor load, or when the windings are connected according to a "star - zigzag circuit with a zero wire", phase asymmetry occurs at the output of the step-down transformer, leading to overheating of the motors [ Gimoyan G.G., Leibov PM Relay protection of underground network equipment. M., Nedra, 1970, 280 p.]. Figure 1 shows a graph of the calculated linear voltage at the output of the step-down transformer when a phase failure occurs at its input with the above transformer connections. The graph shows that the known prototype does not detect such a cliff.

The problem to which the claimed invention is directed is to provide a method for monitoring phase loss in a three-phase network and a device for its implementation with increased reliability of protection of three-phase equipment by detecting a phase failure in a three-phase network both at the output of the step-down transformer and at its input.

The technical result of the invention is achieved by the fact that in the method of monitoring phase loss in a three-phase network, based on the determination of instantaneous values of linear voltages as the difference of instantaneous values of phase voltages, measured relative to the formed neutral point, by forming a low-voltage analogue of the monitored network voltage, rectifying the three-phase voltage and smoothing the rectified voltage, and before rectification reduce the controlled three-phase voltage of the network, form a predetermined level the smoothed voltage, raise the voltage of the neutral point to a predetermined level relative to the common point of the circuit and determine the period of phase voltages by transitions through a given level, determine the phase failure by the value of the asymmetry coefficient, calculated as the ratio of the effective values of the voltage of the reverse and direct sequence calculated using the effective values of the linear voltages, which are determined by the measured phase voltages for the period.

The technical result of the invention is achieved by the fact that in the device for implementing this method, containing inputs for connecting to a three-phase voltage source, a three-phase rectifier, to the outputs of which a smoothing capacitor is connected, resistors, some of whose outputs are connected in phase with the inputs for connecting to a three-phase voltage source, and others are connected in phase with the terminals of the following resistors, the other terminals of which are connected to each other and form a neutral point, operational amplifiers, inputs connected operating in phase with common points of resistors, and outputs in phase with ADC inputs connected by their outputs to the processor, an operational amplifier, capacitors and resistors are additionally introduced, the operational amplifier being connected to a common point of series-connected resistors connected to the outputs of a three-phase rectifier, and the output to with a neutral point, and each of the inputs for connecting to a three-phase voltage source is connected in phase with a capacitor and a resistor connected in series, where the terminals are a resistor s connected in phase with the inputs of a three-phase rectifier.

When analyzing other well-known technical solutions, the applicant did not reveal a set of features that distinguish the claimed technical solution from the prototype, leading to increased reliability of protection of three-phase equipment by detecting a phase failure in a three-phase network both at the output of the step-down transformer and at its input. Also, the use for the purpose of monitoring phase failure in a three-phase network of such a value as the asymmetry coefficient with respect to the effective values of the voltage of the reverse and direct sequence was not revealed. That is, we can conclude that the claimed technical solution meets the criteria of "novelty" and "inventive step".

The essence of the invention is illustrated by drawings, in which Fig. 1 is a graph of line voltage during phase failure occurring at the input of a step-down transformer (prototype), in Fig. 2 is an electrical circuit diagram of a device for monitoring phase loss in a three-phase network, in Fig. 3 - graph of the voltage at the inputs of the ADC during normal operation, figure 4 is a graph of the voltages at the inputs of the ADC with a phase failure that occurred at the output of the step-down transformer, figure 5 is a graph of linear voltage with a phase failure that occurred at the output of the bottom Fig. 6 is a graph of the voltages at the inputs of the ADC with a phase failure occurring at the input of the step-down transformer; Fig. 7 is a graph of the linear voltages with a phase failure occurring at the input of a step-down transformer.

A method of controlling phase failure in a three-phase network consists in reducing the controlled three-phase voltage of the network before rectification, forming a predetermined level of the smoothed voltage, raising the voltage of the neutral point N to a predetermined level relative to the common point O of the circuit, and determining the period of phase voltages by transitions through a predetermined level, according to the current values of the linear voltages of the reverse and direct sequence U ₂ , U ₁ , their asymmetry coefficient K _U2 = U ₂ / U ₁ is estimated. The effective values of the voltages of the reverse and direct sequence are determined by the formulas:

where U _AB , U _BC , U _CA are the effective values of the linear voltages.

When K _2U exceeds the threshold value (0.15 <K _2U <0.25), phase failure in a three-phase network is determined. Such a solution makes it possible to detect phase failure in a three-phase network both at the output of the step-down transformer and at its input.

A schematic diagram of a phase loss monitoring device in a three-phase network is presented in figure 2, where the following notation is adopted: 1 - source of three-phase voltage, 2, 3, 4, 5, 6, 7, 21, 22, 23, 24, 25 - resistors, 8, 9, 10, 26 — operational amplifiers, 11, 12, 13 — ADC, 14 — processor, 15 — three-phase rectifier, 16 — smoothing capacitor, 17 — ADC to processor connection bus, 18, 19, 20 — capacitors.

A phase-loss monitoring device in a three-phase network with inputs for connecting a three-phase voltage source 1 with phases A, B, C, where resistors 4 and 7, 3 and 6, 2 and 5 are connected in series to each of the inputs , 7 are connected to each other and form a neutral point N. Phase to the common points of resistors 4 and 7, 3 and 6, 2 and 5 are connected to the inputs of operational amplifiers 8, 9, 10, outputs connected in phase to the inputs of the ADC 11, 12, 13, the outputs of which through the bus 17 are connected to the processor 14. To each of the inputs of the phases A, B, C are connected connected capacitors and resistors 18 and 21, 19 and 22, 20 and 23, where the outputs of resistors 21, 22, 23 are connected to the inputs of a three-phase rectifier 15, between the positive and negative outputs of which a smoothing capacitor 16 is connected, resistors 24, 25 are connected in series. To the common point of the resistors 24 and 25 is connected the input of the operational amplifier 26, the output connected to the neutral point N.

A device for monitoring phase loss in a three-phase network operates as follows. A controlled three-phase voltage of source 1 is supplied to the inputs of the device. The ADC 11, 12, 13 measure the voltage at each point a, b, c, respectively, relative to the common point O of the circuit (figure 3). The neutral point N is shifted to a predetermined level N = 2.5 (Fig. 3), the formation of which is performed by resistors 24, 25 and an operational amplifier 26. The indicated voltage is obtained by reducing the voltage in phases A, B, C of the capacitors 18, 19, 20 and resistors 21, 22, 23, respectively, and it is necessary to determine the voltage period of the phases A, B, C from the voltage transitions at points a, b, c through a given level. The second advantage of lowering the voltage with capacitors 18, 19, 20 and resistors 21, 22, 23 is that after rectifying it, the voltage Upit is obtained relative to the common point О of the circuit, which is necessary to power the ADC 11, 12, 13, central processor 14 and operational amplifiers 8 , 9, 10, 26. The central processor 14 measures the voltage period of phases A, B, C by transitions through a given voltage level at points a, b, c and reads their instantaneous values through buses 17, determines the instantaneous values of linear voltages U _AB , U _BC , U _CA , asymmetry coefficient K _2U with respect to the effective values of the voltages of the reverse and direct sequence U ₂ , U ₁ according to formulas (1), (2), K _2U = U ₂ / U ₁ calculated using the effective values of the linear voltages U _AB , U _BC , U _CA , which are calculated from the measured instantaneous stress values at points a, b, c for the period.

If the phase at the output of the step-down transformer is broken, for example, phase C, the voltage form at points a, b, c will take the form shown in Fig. 4, and the form of the calculated linear voltages is shown in Fig. 5, and the value of the asymmetry coefficient K _2U will be 1 , which is definitely more than the threshold value (0.15 <K _2U <0.25). This fact is sufficient reason to reliably detect phase failure.

When the phase at the input of the step-down transformer is broken, for example, phase C, the voltage form at points a, b, c takes the form shown in Fig.6, and the form of the calculated linear voltages is shown in Fig.7, and the value of the asymmetry coefficient K _2U will be more than the threshold values (0.15 <K _2U <0.25). This fact is also sufficient reason to reliably detect phase failure.

Tests of the claimed device that implements the claimed method of monitoring phase loss in a three-phase network confirmed the operability, high efficiency of the proposed method and high reliability of protection of three-phase equipment in the event of phase failure both at the output of the step-down transformer and at its input.

Claims (3)

1. A method of monitoring phase loss in a three-phase network, based on the determination of instantaneous values of linear voltages as the difference between the instantaneous values of phase voltages measured relative to the formed neutral point, by forming a low-voltage analogue of a controlled three-phase network voltage, rectifying it and smoothing the rectified voltage, characterized in that before rectification, they reduce the controlled three-phase voltage of the network, form the specified level of the smoothed voltage, raise the voltage tral point on a predetermined level with respect to circuit common point and determining the period of the phase voltages on transitions across a predetermined level, determined by phase loss unbalance value coefficient calculated as the ratio of the feedback current and voltage values of the positive sequence, calculated using linear operating voltages. 2. The method of monitoring phase loss in a three-phase network according to claim 1, characterized in that the effective values of the linear voltages are determined by the measured phase voltages for the period. 3. The device for implementing the method according to claim 1, containing inputs for connecting to a three-phase voltage source, a three-phase rectifier, to the outputs of which a smoothing capacitor is connected, resistors, some of whose outputs are connected in phase with inputs for connecting to a three-phase voltage source, and others are connected in phase with the terminals of the following resistors, the other terminals of which are connected to each other and form a neutral point, operational amplifiers, inputs connected in phase with common points of the resistors, and outputs in phase with ADC inputs connected by its outputs to the processor, characterized in that an operational amplifier, capacitors and resistors are additionally introduced, the operational amplifier being connected to a common point of series-connected resistors connected to the outputs of a three-phase rectifier, and the output to a neutral point, and each of the inputs for connecting to a three-phase voltage source is connected in phase with a capacitor and a resistor connected in series, where the outputs of the resistors are connected in phase with the inputs of a three-phase th rectifier.

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