RU2556332C1 - Leakage current monitor in load of single-phase rectifier - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: monitor comprises two sensors sensing the strength of an external magnetic field, which are placed at current feeding and draining wires coupling the load to a single-phase bridge rectifier. At that outputs of sensing elements of the field strength sensors are connected to the first and second input of the comparator respectively through the relevant analogue amplifiers and narrow-band filters, while the output of the comparator is coupled to an indicator.

EFFECT: potential identification of leakage current in the load of a single-phase bridge rectifier by a non-contact way in real time without the disconnection of the rectifier from the functioning process.

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Description

The invention relates to electrical engineering and can be used for automatic non-contact determination of the presence of real-time leakage current in the load of a single-phase bridge rectifier AC while reducing the value of its insulation resistance.

The presence of leakage current is considered an extremely undesirable phenomenon in electrical equipment. It occurs in the case of a significant decrease in insulation resistance in current-carrying veins of cables of electrical installations (load). This fact affects the energy performance of the equipment. If the leakage current continues to increase (due to a decrease in insulation resistance), then a short circuit may occur between the current-carrying conductors or one of the conductors and the housing, which may lead to failure of the entire equipment.

In this regard, the problem of timely detection of the fact of the presence of leakage currents in electrical installations is very urgent. This task is especially important for special equipment, the operation of which is associated with the risk of emergency situations with severe consequences. For example, the appearance of potential (leakage current) on the case of electrical installations working with aggressive liquids or explosive substances can lead to disruption of control and protection processes, the formation of false operation circuits for equipment, sparking, etc., which, in turn, can lead to disastrous consequences.

In practice, in the vast majority of cases, it becomes necessary to determine the fact of the appearance of this parasitic current. And only after this in some cases there is a need to directly measure the value of the leakage current or the value of the corresponding insulation resistance.

Various types of galvanometers, mechanical (electrostatic) and dynamic electrometers are widely used as low-current current meters in electrical equipment [1]. Along with high measurement accuracy and high sensitivity, a distinctive feature of these devices is the complexity of the designs and algorithms for measuring, the high cost, as well as the need for electrical contact of the measuring circuits of the devices with the control object.

A known method of determining the resistance of current leakage paths to earth in electrical systems [2], which assumes a number of measurements of leakage currents to earth and the total current of the system, the preparation of a cumbersome system of linear equations by the number of electrical circuits with its subsequent solution, during which the current is determined leaks. The disadvantages of the method are the complexity of the implementation of the algorithm for determining the insulation resistance, as well as the need to ensure galvanic communication between the monitoring equipment and the electrical system.

A known method of monitoring the insulation resistance and protecting the electric network [3], in which it is assumed that there is an additional source of measuring voltage in the form of a periodic sequence of pulses of a certain shape, measuring the leakage current for two corresponding intervals, calculating the insulation resistance by the formula, comparing the obtained value with the given values of the resistances . The disadvantages of the method are the complexity of the implementation and the need for galvanic communication between the control equipment and electrical equipment.

Closest to the proposed invention is a method for detecting leakage currents, the possibility of their occurrence and the search for places of their occurrence in power supply systems [4]. The invention is intended to detect leakage currents and to search for places of their occurrence in power supply systems having branched sections. A device that implements this method consists of an audio signal generator, an induction sensor and a current sensor. The method involves, in particular, measuring current imbalances in the power supply cable and outgoing load power cables. The advantage of the method is the relative simplicity of its implementation, because it does not measure the value of the leakage current or the insulation resistance, but only determines the presence of this current.

The disadvantage of the prototype is the contact method for detecting leakage current in the cable, i.e. the need to ensure galvanic communication of the device that implements the method with the object of control.

The aim of the invention is to control the presence of leakage current in the load of a single-phase bridge rectifier in a non-contact way in real time.

It is known [5] that non-contact methods of monitoring the performance of various devices have a number of significant advantages compared to contact methods:

- in the controlled devices does not occur any changes affecting their main parameters and characteristics;

- it becomes possible, by indirect signs, to detect hidden defects in devices or to identify features that entail potential malfunctions of controlled devices;

- it becomes possible to obtain information about the technical condition of the monitoring object in real time.

In addition, the device [6], which implements one of the non-contact methods, allows to achieve high accuracy in measuring current and voltage parameters.

This goal is achieved by the fact that the device analyzes the information content of the output signals of two sensors of the external magnetic field, located on the current-carrying and current-conducting wires connecting the load to a single-phase bridge rectifier, while the amplitude of the spectral components of the sensor signals equal to 2ω is used as an information parameter (ω is the frequency of the supply rectifier of the input voltage), which after amplification are allocated using narrow-band filters. The fact that at the output of the device for comparing the difference signal the amplitudes of the spectral components of the signals of the intensity sensors will indicate the appearance of a leakage current in the load of a single-phase bridge rectifier.

In the device in question, information on the presence of a leakage current is obtained non-contact, based on an analysis of the spectral composition of the output signals of two sensors of the external magnetic field strength, located on the current-supplying and current-conducting wires connecting the rectification circuit to the load. To solve this problem, a wide range of magnetosensitive sensors (induction, magnetodiode, based on the Hall effect, etc.) can be used. The choice of type of sensor can be determined by various factors: ensuring the necessary measurement sensitivity, features and ease of placement (mounting), cost considerations, etc. As such a sensor for the implementation of the invention, a universal integrated measuring transducer of current and voltage parameters during operation of electrical equipment for various purposes [6] that meets the criteria of sensitivity, ease of installation and low cost can be used.

Figure 1 presents a functional diagram of a device for monitoring the leakage current in the load of a single-phase rectifier. The device includes two sensors of the external magnetic field strength 1 ₁ and 1 ₂ (D1 and D2), each of which consists of a sensitive element (SE), which is placed in a microinductive inductance solenoid hub of several turns of wire wound around a dielectric cylindrical tube. These sensors are connected according to the scheme of the current transformer respectively to the current-supplying and current-conducting wires connecting the single-phase bridge rectifier 2 and load 3. The outputs of the sensitive elements of the sensors 1 ₁ and 1 ₂ are connected to the corresponding amplifiers 4 ₁ and 4 ₂ (U1 and U2), the outputs of which are connected to the inputs of narrow-band filters 5 ₁ and 5 ₂ (F1 and F2). The outputs of the narrow-band filters are connected respectively with the first and second inputs of the comparison device 6 (CSS), the output of which, in turn, is connected to the indicator 7 (I).

A device for monitoring the leakage current in the load of a single-phase rectifier operates as follows.

The input single-phase alternating supply voltage ~ u _{П is} converted (increases or decreases) by the transformer Tr and applied to the input of the bridge rectifier 2. The rectified ripple current flows through the circuit: (+) rectifier 2, sensor solenoid-concentrator 1 ₁ , load 3, solenoid-concentrator sensor 1 ₂ , (-) rectifier 2.

In the sensor 1 _{1, the} wire forming the solenoid hub is current-carrying and current I _LOD flows through it, and in the sensor 1 _{2 a} similar wire is current-conducting and the current I _OT correspondingly flows through it. External magnetic fields created by these currents induce electromotive force (emf) in the sensors D1 and D2, as a result of which the sensitive elements of the sensors will generate signals proportional to the magnitude of the currents flowing through the wires. After amplification in amplifiers 4 ₁ and 4 _2, these signals are fed to narrow-band filters 5 ₁ and 5 ₂ tuned to a frequency of 2ω, where the amplitudes of the spectral component of the signals with a given frequency are extracted.

In the event that there is no leakage current in the load, i.e. I _POD = I _POT (or I _POD -I _POT = 0), then the amplitudes of the spectral components with a frequency of 2ω of the sensor signals will also be equal, and there will be no difference signal at the output of the comparison device 6. Indicator 7 will not work.

In the event that there is a load current I leak _UT, then the first law of Kirchhoff _AML I> I _{PTV AML} or I = I + I _{0TB UT.} Then the magnitude of the amplitude of the spectral component from the output of the sensor D ₂ located on the current-carrying wire will be less than the magnitude of the amplitude of the spectral component from the output of the sensor D ₂ located on the current-carrying wire by a value proportional to the value of the leakage current I _UT . As a result of comparing these amplitudes, the difference signal detected by the indicator 7 will appear at the output of the comparison device 6. The operation of the indicator 7 (for example, when the LED is on or the sound source is turned on) indicates the appearance of a stray leakage current in the load (electrical equipment powered by the rectifier).

Thus, the proposed device with high reliability and accuracy non-contact determines the presence of a leakage current in electrical equipment powered by a single-phase bridge rectifier.

In addition, this device is very simple, and therefore convenient to operate: it is easy to connect to an existing leakage current monitoring system by simply winding the corresponding supply wires to the magnetic field sensors.

Information sources

1. Gribanov Yu.I. Measurement of weak currents, charges and high resistances. M.-L., Gosenergoizdat, 1962.

2. Sedov A.V., Lachin V.I., Raspberry A.K. A method for determining the resistance of current leakage paths to earth in electrical systems. RF patent for the invention No. 2010247, 1994.

3. Malafeev SI., Mamai B.C. and others. A method of controlling insulation resistance and protecting the electrical network. RF patent for the invention No. 2144679, 2000.

4. Grigoriev O.A., Petukhov B.C., Sokolov V.A. A method for detecting leakage currents, the possibility of their occurrence and the search for places of their occurrence in power supply systems. RF patent for the invention No. 2208233, 2003 (prototype).

5. Ermolov I.N., Ostanin Yu.Ya. Methods and means of non-destructive quality control. M .: Higher school, 1982.

6. Sukiyazov A.G., Prosyannikov B.N. and others. Integrated measuring transducer of parameters of currents and voltages during operation of electrical equipment for various purposes. RF patent for utility model No. 100291, 2010.

Claims (1)

A device for monitoring the leakage current in the load of a single-phase rectifier, comprising an indicator, characterized in that the device includes two external magnetic field strength sensors placed on the current-supplying and current-conducting wires connecting the load to the single-phase bridge rectifier, and the outputs of the sensitive elements of the voltage sensors are connected respectively to the first and second inputs of the comparison device through the corresponding similar amplifiers and narrow-band filters, and the output of the device with avneniya associated with the indicator.