RU2370778C1 - Contact-free current metre - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: contact-free current metre comprising secondary winding (1) of current transformer, generator (2) and receiver (5) of magnetic flux, optoelectronic converter (8) and measurement (9), relay protection and automatics devices. Generator (2) and receiver (5) of magnetic flow are arranged in the form of coaxially installed cylindrical induction coils. Induction coil of magnetic flux generator (2) is connected to the secondary winding of (1) current transformer, and induction coil of magnetic flux receiver (5) is connected via optoelectronic converter (8) to measurement (9), relay protection and automatics devices. In order to reduce magnetic flux of dispersion, not engaged with induction coil of magnetic flux receiver (5), with preservation of device size and its reliable operation, induction coil of magnetic flux generator (2) and receiver (5) are equipped with magnetic flux concentrators (3, 6) that are coaxial with them and identical in shape, accordingly. Each of magnetic flux concentrators (3, 6) is made of material with high magnetic permeability, has cylindrical part installed in cavity of according induction coil, and outside of it - external part, cylindrical section of which is located on the side of induction coil, is aligned with section in the form of truncated cone along its larger base and is made with D diametre not less than external diametre d of induction coil. External parts of magnetic flow concentrators (3, 6) by smaller bases of truncated cones, on which, coaxially to magnetic flow concentrators (3, 6) there are axisymmetric electrostatic screens fixed (4, 7), made of non-magnetic material, are inverted to each other.

EFFECT: higher accuracy of measurement due to reduction of losses of magnetic flux that induces current in induction coil of magnetic flux receiver.

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Description

The invention relates to electrical engineering and can be used to measure the magnitude of the alternating current flowing through the wires of high-voltage power lines and high-voltage equipment of substations.

At present, a device is known (Japanese Patent No. 6075081 V, IPC: G01R 15/22; 15/18; 19/00, published September 21, 1994, [1]), which makes it possible to measure current in the wires of power lines and in high-voltage equipment while ensuring electric strength between live parts at high potential and measuring devices, as well as relay protection and automation devices at zero or very low potential (up to 220 V).

This is achieved by connecting to the secondary winding of a current transformer at high potential a load in the form of two LEDs connected in parallel and connected in the opposite direction. With this connection scheme, the intensity of the light emitted by the LEDs is proportional to the amount of current flowing through the secondary and primary windings of the current transformer. The photodiodes through an insulating optical fiber are connected to photoelectric converters located at low potential, and those, in turn, with a summing device, the signal from which is transmitted to the low-pass filter, after which it can already be measured without interference caused by the electronic circuit of the converters and the adder current value in each half-cycle of industrial frequency.

However, this design [1] has a significant drawback, namely, that in order to obtain a high accuracy class when measuring the primary current, the LEDs must have absolutely identical current-voltage characteristics and absolutely identical values of the external quantum yield at the same voltage values.

In addition, the introduction of an optical fiber under full operating or test voltage during operation significantly reduces the dielectric strength between the parts of the device at high and low potentials, and also reduces the reliability of the structure due to aging of the fiber.

The closest in technical essence to the proposed device and selected as a prototype is a non-contact current sensor (Application JP No. 9005360 A, IPC: G01R 15/18; 15/22; 15/14, published January 10, 1997, [2]) comprising a magnetic flux generator in the form of an inductor connected to the secondary winding of a current transformer worn on a live wire under high voltage, and a magnetic flux receiver in the form of an inductor located coaxially with the inductance coil of the magnetic flux generator and connected oh with an amplifier, the signal from which is fed to measuring devices, relay protection and automation.

However, the known device [2] has a significant drawback. It cannot be applied at high and ultrahigh voltages, since the distance between the magnetic flux receiver and the magnetic flux generator must be significant in order to ensure the electric strength of the insulation gap.

At high and ultra-high voltage, the distance between the inductor coils of the generator and the receiver can be so large that the receiver inductance coils with a very small fraction of the magnetic flux generated by the generator inductance coils. This leads to a decrease in the sensitivity of the receiver and, as a result, to an increase in the measurement error due to the influence on the receiver of external magnetic fields that are not created by the measured current.

To reduce the error of changes in this case, while maintaining the distance between the inductor coils of the generator and receiver, significantly increase the number of turns of wire in the coils, increase the inner diameter of the inductor of the generator and receiver, which will lead to an increase in the dimensions, weight and price of the device.

The objective of the proposed technical solution is to create the design of a non-contact current meter, which allows to reduce the magnetic flux scattering, not coupled to the inductance coil of the receiver of the magnetic flux, while maintaining the dimensions of the measuring device.

The technical effect of using the proposed non-contact current meter is to increase the accuracy of the measurement by reducing the loss of magnetic flux inducing current in the inductor of the magnetic flux receiver.

The solution of the problem and the corresponding technical result is achieved by the fact that in the proposed non-contact current meter containing the secondary winding of the current transformer, the generator and receiver of the magnetic flux, the optoelectronic converter and measuring devices, relay protection and automation, the generator and receiver of the magnetic flux are made in the form of placed coaxially cylindrical inductors, the ends of the inductance coil of the magnetic flux generator connected to the ends of the secondary winding trans a current romator mounted on the busbar, and the ends of the inductance coil of the magnetic flux receiver are connected to the corresponding inputs of the optoelectronic converter, the outputs of which are connected to measuring devices, relay protection and automation, the inductor of the generator and the magnetic flux receiver are equipped with concentrators that are coaxial with them and identical in shape magnetic flux, wherein each magnetic flux concentrator is made of a material with high magnetic permeability, has a floor the spine of the corresponding inductance coil, the cylindrical part and the external part located outside of it, the cylindrical portion of which is located on the side of the inductor, is aligned with the section in the form of a truncated cone along its larger base and has a diameter D of at least the outer diameter d of the inductor, and the outer parts of the magnetic concentrators flow with smaller bases of sections in the form of truncated cones, on which axisymmetric electrostatic screens from non-magnetic material facing each other.

The cylindrical parts of the magnetic flux concentrators placed in the cavity of the inductance coils provide an increase in the magnetic field induction in the inductance coils of the generator and receiver of the magnetic flux.

In order to reduce the scattering of the magnetic flux by the extreme turns of the inductor, the cylindrical portion located on its side of the outer part of each magnetic flux concentrator must have a diameter D equal to or greater than the outer diameter d of the corresponding inductance coil.

Made in the form of a truncated cone, the portion of the outer part of the magnetic flux concentrator provides the concentration of the main magnetic flux connecting the two inductors. It is important that the angle formed by the intersection of the cut of the smaller base of the truncated cone with its lateral surface be covered by an electrostatic screen in order to increase the electrical strength of the insulation by aligning the electric field, and therefore, to ensure the reliability of the entire device while maintaining its axial and radial dimensions.

It follows that the above set of distinctive features provides improved measurement accuracy while maintaining the dimensions and reliability of the device.

Comparison of the proposed design of a non-contact current meter with the prior art and the lack of a description of a similar technical solution in known sources of information allows us to conclude that the proposed device meets the criterion of "novelty."

The inventive device is characterized by a combination of features exhibiting new qualities, which allows us to conclude that the criterion of "inventive step".

The figure schematically shows a non-contact current meter (in section) and a current-carrying bus.

The proposed measuring device comprises a secondary winding 1 of a current transformer, a magnetic flux generator 2 with a magnetic flux concentrator 3 located in its inductance coil, which is equipped with an electrostatic screen 4, and a magnetic flux receiver 5 with a magnetic flux concentrator 6 located in its inductance coil, which is equipped with an electrostatic screen 7. The receiver of the magnetic flux 5 is connected to the corresponding inputs of the optoelectronic converter 8, the outputs of which are connected to devices 9 measurement, relay protection and automation, for example, using optical or electrical communications.

The generator 2 and the receiver 5 of the magnetic flux are placed in the housing 10 of insulating material and mounted on opposite flanges 11 and 12 of the housing 10, respectively. On the flanges 11 and 12 made of non-magnetic material, low-voltage bushings 13 and 14 are installed to connect the magnetic flux generator, respectively 2 with a secondary winding 1 of the current transformer and for connecting the magnetic flux receiver 5 to the optoelectronic converter 8.

In this case, the magnetic flux concentrators 3 and 6 are made of a material with high magnetic permeability and have a cylindrical part located in the cavities of the respective inductors, as well as an external part located outside the coils. The outer part of each of the concentrators 3, 6 includes a cylindrical section located on the side of the inductor and a section made in the form of a truncated cone, which are aligned on the larger base of the truncated cone. Moreover, the diameter D of the cylindrical section and the larger base of the truncated cone must be at least the outer diameter d of the inductor.

The magnetic flux concentrators 3 and 6 with the smaller bases of the sections in the form of truncated cones are facing each other. Axially symmetric electrostatic screens 4 and 7, respectively, are mounted coaxially with the magnetic flux concentrators 3 and 6 on the smaller bases of the truncated cones.

The figure to illustrate the measurement process shows the current-carrying bus 15, which is both the primary winding of the current transformer and the conductor, the current of which is measured.

The measuring device operates as follows. With the passage of current through the current-carrying bus 15 in the secondary winding 1 of the current transformer and in the inductance coil of the magnetic flux generator 2, current arises, and a magnetic flux is generated inside the inductance coil of the magnetic flux generator 2, part of which passes inside the inductance coil of the magnetic flux receiver 5. To increase the fraction of magnetic flux passing through the inductance coil of the magnetic flux receiver 5, and thereby to reduce the scattering magnetic flux, to the inductance a magnetic flux nerator 2, a magnetic flux concentrator 3 is inserted, and a magnetic flux concentrator 6 made of a material with high magnetic permeability is inserted into the inductor of the magnetic flux receiver 5. Electrostatic screens 4 and 7, covering the sharp edge on the smaller diameter base sections in the form of truncated cones of the magnetic flux concentrators 3 and 6, respectively, align the electric field between these magnetic flux concentrators 3 and 6, which are under full voltage, and thereby reduce the distance between them, which, in turn, allows to increase the proportion of magnetic flux coupled to the inductance coil of the magnetic flux receiver 5, and to increase the measurement accuracy of the proposed device triplets.

Claims (1)

A non-contact current meter containing a secondary winding of a current transformer, a magnetic flux generator and receiver, an optoelectronic converter and measuring devices, relay protection and automation, the magnetic flux generator and receiver are made in the form of coaxially arranged cylindrical inductors, the ends of the inductance coil of the magnetic flux generator connected to the ends of the secondary winding of the current transformer mounted on the busbar, and the ends of the receiver inductance coil are magnet of the flux are connected to the corresponding inputs of the optoelectronic converter, the outputs of which are connected to measuring devices, relay protection and automation, characterized in that the inductance coils of the generator and the magnetic flux receiver are provided with coaxial magnetic flux concentrators with identical shapes, with each magnetic flux concentrator made of a material with high magnetic permeability, has a cylindrical part located in the cavity of the corresponding inductance coil and accommodates outside its outer part, the cylindrical portion of which is located on the side of the inductor, is aligned with the section in the form of a truncated cone on its larger base and has a diameter D of at least the outer diameter d of the inductor, with the outer parts of the magnetic flux concentrators having smaller bases of sections in the form of truncated cones on which axisymmetric electrostatic screens of non-magnetic material are fixed coaxially with the magnetic flux concentrators are facing each other.