SU1053220A1 - Method of determining advance time for synchronizer (versions) - Google Patents

Abstract

1. A method for determining the timing advance of a synchronizer by measuring a time counter from the time the synchronizer operates to the point where a zero phase shift occurs between the voltages applied to the synchronizer inputs and controlling the phase shift during each voltage frequency period, in order to simplify the method in determining the lead time in laboratory conditions, they form two sawtooth voltage, convert each of them into harmonic voltage according to the order cosine, use the obtained voltages as voltages applied to the synchronizer inputs, and the moment of occurrence of a zero phase shift between voltages is determined by comparing the instantaneous values of sawtooth voltages with each other during periods of coincidence of the harmonic polarity The time of the occurrence of a zero shift (L phases between voltages at the instant of equality of instantaneous values of sawtooth voltage. el ooo yu yu

Description

2. A method for determining the timing advance of a synchronizer By measuring a time counter from the time the synchronizer responds to the point where a zero phase shift occurs between voltages connected to the synchronizer inputs and monitoring the phase shift during each voltage frequency period that to simplify the method in determining the lead time in laboratory conditions, they form two voltages of a triangular shape, convert each of them to a harmonic voltage

sine-shaped forms, use the obtained voltages as voltages applied to the synchronizer inputs, and the moment of occurrence of a zero phase shift between voltages is determined by comparing the instantaneous values of triangular voltages to each other during periods of coincidence of the signs of their rate of change and fix the moment of occurrence of a zero phase shift between voltages at the instant of equality of instantaneous voltages of a triangular shape. .

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The invention relates to electrical engineering, in particular to automatic synchronizers of electric machines, and can be used in their configuration and testing.

There is a known method for determining the time one of a synchronizer by measuring the time interval from the moment the synchronizer is triggered to the moment that a zero phase shift occurs between the leading and synchronized electrical systems. The method is carried out by oscillographing the process of changing the voltage of the beating (the voltage difference between the phases of the synchronized and leading systems of the same name), determining on the oscillogram a zero value of the angle between the voltages of the synchronized and leading electric systems, including the minimum value of the beating voltage, and calculating lead time, taking into account the oscilloscope sweep speed. In this method, the determination of the timing of the advance of the synchronizer is associated with the necessity of fixing, using an oscilloscope, the process of relative motion of the synchronized systems and the timing of the synchronizer 1.

The disadvantage of this method is the significant complexity of waveform processing: finding, using graphical methods, the moment of occurrence of the required angle between the voltages of synchronized systems and recalculating the spatial gap between the specified time and the timing of the synchronizer at the measured lead time.

The closest to the invention according to the technical essence is a method for determining the timing advance of a synchronizer by measuring a time counter from the time the synchronizer triggers until the zero phase shift occurs between voltages connected to the synchronizer inputs, while the zero phase shift is monitored during each frequency period tension The monitoring is carried out by integrating a signal proportional to the frequency of the master system, as well as a signal proportional to the slip module, and comparing the results obtained 2.

However, to implement the known method, it is necessary to have rather complicated and expensive frequency and slip sensors, which, when checking the synchronizer in laboratory conditions, require an additional increase in the power of the generators, which leads to higher costs when setting up and determining the timing of the synchronizer in laboratory conditions.

The purpose of the invention is to simplify the method for determining the timing of a synchronizer ahead in laboratory conditions.

The goal is achieved in that according to the method of determining the lead time of the synchronizer in the first embodiment, which includes measuring the time between the time between the synchronizer and the zero phase shift between the voltages applied to the synchronizer inputs and the control of the phase shift during each period stress frequencies form two sawtooth stresses, convert each of them to harmonic stress according to the cosine law, use Voltages as voltages applied to the synchronizer inputs, and the time of occurrence of a zero phase shift between voltages is determined by comparing the instantaneous values of sawtooth voltages with each other during periods of coincidence of the harmonic polarity of the voltage and fixing the time when zero shear occurs phases between voltages at the instant of equality of instantaneous values of sawtooth voltage. In addition, according to the second variant, two triangular voltage voltages are formed, each of them is transformed into harmonic voltage according to the sine law, the resulting voltages are used as voltages applied to the synchronizer inputs, and the moment of zero phase shift between the voltages They are determined by comparing the instantaneous values of triangular voltage between each other during periods of coincidence of the signs of the rate of their change and record the time when a zero phase shift occurs between the voltages at the time equalities of instantaneous triangular stress. FIG. 1 and 2 show timing diagrams of sawtooth input and harmonic output voltages; in fig. 3 shows timing diagrams of input triangular shapes and harmonic output voltages. The diagrams show Argillo (triangular) voltages; Signals a (and aa which determine the polarity of the harmonic signal in the first variant and the sign of the rate of change of voltage in the second variant, the phases and instantaneous values of the harmonic voltage U and U j. Indices 1 and 2 indicate the ratio of the listed parameters to Figures 1 and 2 illustrate the case when the frequency of the input voltage A i is higher than the frequency of voltage A. At the same time, the diagrams shown in Fig. 1 and 3 correspond to f "fj 0. and the diagrams shown in Fig. 2, - f, fj L The essence of the proposed method consists The following. Saw-shaped voltages of different frequencies are transformed into harmonic voltages according to the cosine law, which are determined within the half-period by the following relationship UM-COS A, where UM is the amplitude of the harmonic voltage. The frequency of the output voltage of the harmonic form is twice as low. frequency of the sawtooth voltage. A change in the signal a corresponds to a change in the polarity of the voltage that is fed to the inputs of the synchronizer, and these voltages are in phase with the voltage of the sawtooth form s. When the synchronizer is triggered, a time counter is started up. By comparing the instantaneous values of the sawtooth voltage during the periods t i- t 2 coincidence of the polarities of the signals a i and a, determine the time t j the coincidence of the phases of the voltage of the harmonic form according to the condition of equality of the instantaneous values of the saw voltage and stop the time counter. The readings of the time counter at time tj correspond to the determined time of the advance of the synchronizer, since at this time the equality A i and A j corresponds to the equality of the phases and voltages of the harmonic form and 1 and g. The second variant of the proposed method is that the voltage is triangular forms of different frequencies are transformed into harmonic voltages according to the sine law, which are determined by the following relationship and Uw-sin A. The signal a (Fig. 3) corresponds to a change in the sign of the rate of change of triangular and harmonic voltage f Forms that are in-phase. The voltage of the harmonic form is fed to the inputs of the synchronizer and when the synchronizer is triggered, a time counter is started. By comparing the instantaneous values of triangular stresses during periods t it, the signs of the signs of the rate of change of triangular or harmonic stresses coincide, determine the moment t 3 coincidence of the phases of the harmonic stresses according to the condition of equality of instantaneous values to triangular stresses and stop the counter of time. The readings of the time counter correspond to the determined lead time, since the equality А i and А 2 corresponds to the equality f, and f, the voltage stresses of the harmonic form Ui and and The method can be realized by using cosine-sine-type converters, forcing logical signals corresponding to polarity or the sign of the rate of change of voltages, logical equivalence schemes and coincidence, as well as a null organ, the output voltage of which appears when the input voltages are equal. The technical and economic advantages of the invention lie in the fact that it makes it possible to determine the timing of the advance of the synchronizer in the laboratory in each frequency period without the need to use complex frequency and slip sensors.

Claims (2)

1. The method of determining the lead time of the synchronizer by measuring the time counter from the moment the synchronizer is triggered until the occurrence of a zero phase shift between the voltages connected to the inputs of the synchronizer, and control the phase shift during each voltage frequency period, characterized in that, in order to simplification of the method when determining lead times in laboratory conditions, they form two sawtooth voltages, convert each of them to a harmonic voltage according to the law insus, use the obtained voltage as the voltage supplied to the inputs of the synchronizer, and the moment of occurrence of a zero phase shift between the voltages is determined by comparing the instantaneous values of the sawtooth voltage with each other during periods of coincidence of the polarities of the harmonious voltage and fix the moment of occurrence of a zero phase shift between the voltages at the time equality of instantaneous values of sawtooth stresses. "Ι-J ___ I___I I R I I, 1 I SU ,, „1053220> 2. The method of determining the lead time of the synchronizer By measuring the time counter of the interval from the moment of operation of the synchronizer to the moment of zero phase shift between the voltages supplied to the inputs of the synchronizer, and control the phase shift during each voltage frequency period, characterized in that, in order to simplify the method when determining lead time in laboratory conditions, they form two triangular stresses, convert each of them into harmonic voltage according to the law of blue CA, use the obtained voltage as the voltage supplied to the inputs of the synchronizer, and the moment of occurrence of a zero phase shift between the voltages is determined by comparing the instantaneous values of the voltage of a triangular shape with each other during periods of coincidence of signs of the rate of change and fix the moment of occurrence of a zero phase shift between the voltages at the time Equality of instantaneous stresses of a triangular shape.