RU2476967C1 - System for power takeoff from three-phase high-voltage overhead transmission line - Google Patents

Abstract

FIELD: electrical engineering.SUBSTANCE: device contains single-circuit supports, each having a lateral cross member, whereon phase conductors of a three-phase line are suspended via HV insulators, a primary transducer with output clamps that are connected to the input clamps of the voltage regulator transducer to the output clamps whereof a load is connected; the primary transducer is designed in the form of flat metal gauze lying on the ground and extending along the phase conductors direction and a section of flat multiconductor cable placed on the flat metal gauze parallel to the phase conductors direction; the cable longitudinal axis is off the projection line of the nearest phase conductor of a three-phase line by a distance equal to the largest one among those of phase conductors projections onto the plane passing through the single-circuit supports; one end of each conductor within the flat multiconductor cable is connected to the common contact point on the metal gauze while the other end is connected to the terminal serving as the first output clamp of the primary transducer, the second output clamp of the primary transducer being the common contact point on the metal gauze.EFFECT: proposed system design simplification.1 dwg

Description

The invention relates to the field of electrical engineering, in particular to secondary power sources for non-contact power take-off from three-phase transmission lines of high voltage.

A known power take-off system from a phase wire current of a three-phase high voltage transmission line, comprising a primary transformer in the form of a current transformer installed at high potential on a support of a high voltage transmission line, whose primary winding is included in the phase wire circuit, a voltage transformer whose primary winding is connected to the secondary winding current transformer, and the secondary winding is connected to the input of the rectifier diode bridge with a smoothing capacitance. The output terminals of the rectifier diode bridge are connected to the input terminals of a voltage stabilizer made according to the DC-DC converter circuit. The output terminals of the DC-DC converter are connected to a power source and a battery connected in parallel to the load (Bunin A.V., Vishnyakov S.V., Gevorkyan V.M., Kazantsev Yu.A. et al. The problem of creating an autonomous integrated measurement power supply high-voltage devices. Abstracts. Proceedings. XXII International Conference "Electromechanics, Electrotechnologies, Electrotechnical Materials and Components" FEEEE-2008., Crimea, Alushta, September 24 - October 4, 2008 Section 2 - Electromechanics, p.297-298.

The disadvantage of such a power take-off system is the design complexity associated with the need to place the primary winding inside the ring coil of the current transformer - the primary converter.

Closest to the proposed power take-off system from a three-phase high voltage transmission line is a power take-off system from phase currents of a three-phase high-voltage transmission line, comprising a primary converter, a rectifying diode bridge with a smoothing capacitance, the output terminals of which are connected to the input terminals of a voltage regulator made by DC-DC converter circuit, and the output terminals of the DC-DC converter are connected to a power source and a battery pack connected in parallel to the load Moreover, it is equipped with a piece of coaxial cable that connects the output of the primary converter to the input of the rectifier diode bridge, the three-phase transmission line is mounted on single-circuit supports with a transverse traverse, the primary converter is made in the form of a multi-turn coil of an insulated copper wire, which is fixed through an insulator on a single-circuit support of a high-voltage three-phase transmission lines below the transverse traverse of a single-chain support at the point of intersection of the circular arc, which is described around the center at point n the distance between the phase wires along the transverse cross-beam of the single-chain support and the vertical drawn from the point of intersection of the vertical part of the support and the transverse cross-beam, with the longitudinal axis of the multi-turn coil directed to the phase wire, more distant from the point at which the multi-turn coil is fixed, and perpendicular to the direction to the second phase wire from the point at which the multi-turn coil is fixed (RF Patent No. 2414035, IPC H02J 3/00 (206/01), publ. 03/10/11).

The disadvantage of such a power take-off system is the design complexity associated with the primary converter and the device for its placement and orientation relative to the phase conductors of the line.

The technical result of the invention is to simplify the design of a power take-off system from a three-phase high voltage transmission line.

This is achieved by the fact that in the known power take-off system from a three-phase transmission line of high voltage, containing single-circuit supports each with a transverse traverse, on which phase wires of a three-phase line are suspended through high-voltage insulators, a primary converter with output terminals that are connected to the input terminals of the converter-regulator voltage, to the output terminals of which the load is connected, the primary converter is made in the form of a flat metal grid lying on the ground and extended along l the direction of the phase wires, with a piece of flat multi-wire cable placed on a flat metal grid, which is parallel to the direction of the phase wire, the longitudinal axis of which is removed from the projection line to the ground of the nearest phase wire of the three-phase transmission line by a distance equal to the largest of the projection distances of the phase wires onto the plane, passing through single-chain supports, with the plane of the segment of the flat multi-wire cable parallel to the plane of the earth, one of the ends of each wire of the flat multi-wire -stand cable connected to the common contact point on a metal grid, and a second end connected to the terminal, which serves as a first output terminal of the primary device, and a second output terminal of the primary device is a general contact point on a metal grid.

The essence of the technical solution is illustrated by the drawing, which shows a diagram of a power take-off system from a three-phase high voltage transmission line.

The power take-off system from a three-phase transmission line of high voltage contains single-circuit supports 1, each with a transverse traverse 2, on which phase wires 4, 5, 6 of a three-phase line are suspended through high-voltage insulators 3, a primary converter 7 with output terminals 8 and 9, which are connected to the input terminals of the converter-voltage regulator 10, to the output terminals 11 and 12 of which the load 13 is connected. The primary converter 7 is made in the form of a flat metal grid 14 lying on the ground and extended along the direction f core wires 4, 5, 6, with a piece of flat multi-wire cable 15 placed on a flat metal mesh 14 that is parallel to the direction of the phase wires 4, 5, 6. The longitudinal axis of the piece of flat multi-wire cable 15 is removed from the projection line 16 to the ground of the nearest phase wire 4 a three-phase transmission line to a distance equal to the largest of the projection distances of the phase wires 4, 5, 6 onto a plane passing through single-chain supports 1. One of the ends 17 of each wire of a flat multi-wire cable 15 is connected to a common contact t point 18 on the metal grid 14. The second end 19 of the wires of the flat multi-wire cable 15 is connected to terminal 21, which serves as the first output terminal of the transducer 7, and the second output terminal of the primary transducer 7 is a common contact point 22 on the metal grid 14.

The system of power take-off from the phase wires of a three-phase transmission line of a high voltage operates as follows.

When placing the metal grid 14 parallel to the direction of the phase wires 4, 5, 6 and placing on a flat metal grid 14 a piece of flat multi-wire cable 15, which is parallel to the direction of the phase wires 4, 5, 6, a potential φ is induced on the conductors 17, depending on the position of the segment conductor flat multi-wire cable 15 relative to the phase wires 4, 5, 6 of a three-phase line. Given the geometric displacement of each of the phase conductors 4, 5, 6 of the three-phase line, which is determined by their suspension on a single-chain support 1 with a transverse traverse 2 through high-voltage insulators 3, from each of the phase conductors 4, 5, 6 on each of the wires of a piece of a flat multi-wire cable 15 induces its own partial component of the total potential. Moreover, taking into account the shift of the initial phases to 120 ° phase voltages in the three-phase line, with the symmetrical position of the conductors 17 relative to the system of phase conductors 4, 5, 6, the total induced potential from all phase conductors 4, 5, 6 on each of the wires of a piece of a flat multi-wire cable 15 turns out to be close to zero. To overcome this phenomenon, which is negative for the primary transducer, the geometric technical asymmetry of the position of each wire of a piece of flat multi-wire cable 15 with respect to the system of phase wires 4, 5, 6 is introduced in the proposed technical solution. It turned out to be optimal for creating the necessary potential on the wires of a piece of flat multi-wire cable 15 to ensure the position of the longitudinal axis of a segment of a flat multi-wire cable 15 remote from the line 16 of the projection onto the ground of the nearest phase wire 4 of the three-phase line on the distance a equal to the largest of the distances of the projections of the phase wires 4, 5, 6 onto the plane passing through the single-chain supports 1. In the drawing, the largest of the distances equal to a corresponds to the phase wire 6. This leads to a violation of the geometric symmetry of each wire of the flat segment multi-wire cable 15 with respect to a symmetrical three-phase voltage system of a three-phase high voltage transmission line. As a result, a potential with respect to ground is induced on each of the wires of a section of a flat multi-wire cable 15. Considering the transverse dimension of the flat multi-wire cable 15, which is insignificant with respect to the transverse geometrical dimensions of the three-phase high voltage transmission line, it can be approximately assumed that the same potential is induced on each of the wires of the cable 15.

The use of a flat metal grid 14 lying on the ground and extended along the direction of the phase conductors 4, 5, 6 increases the effective conductivity of the earth and allows you to double (theoretically, with infinite conductivity of the earth) to increase the induced potential on the wires of a multi-wire cable 15. In fact, the effective conductivity of the earth It turns out to be even less than the conductivity of a flat metal grid 14, due to the small (relative to the wavelength) area occupied by the grid 14, which bounds the region occupied by the surface charge the house of each of the phase wires 4, 5, 6. Therefore, the potential induced on the wires of the length of the flat multi-wire cable 15 is less than theoretically possible.

To implement the primary converter 7, the potential induced on the wires of a segment of a flat multi-wire cable 15 is converted to voltage at its output terminals 8 and 9, which are connected to the input terminals of the voltage regulator-converter 10, to the output terminals 11 and 12 of which the load 13 is connected. , to increase the output power of the primary Converter, the wire section of the flat multi-wire cable 15 are connected in parallel. In this case, one of the ends 17 of each wire of the flat multi-wire cable 15 is connected to a common contact point 18 on the metal grid 14. The second end 19 of the wires of the flat multi-wire cable 15 is connected to the terminal 21, which serves as the first output terminal of the primary transducer 7, and the second output terminal of the primary the transducer 7 is a common contact point 22 on the metal grid 14.

Simplification of the design of the power take-off system from currents in the phase wires of a three-phase transmission line is achieved by the type and a certain offset relative to the axis of the nearest phase wire of the three-phase high-voltage transmission line of the axis of a flat multi-wire cable, which forms a primary converter in combination with a flat metal grid.

The power take-off system from the phase wires of the three-phase high voltage transmission line 220 kV, with a circular industrial frequency ω = 314 rad / s, a suspension height of phase wires 4 and 6 equal to N≈14.5 m, phase wire 5 - N≈17.5 m, in the approximation H >> r ₀ = 6.3 mm, where r ₀ is the radius of the phase wire, insulation thickness Δ≈ = 0.02 mm of wire 17 of the length of the flat multi-wire cable 15, with a diameter of each wire 17 of 0.2 mm, and its length is 100 m, the number of wires 17 in the length of a flat multi-wire cable 15, equal to 10, allows you to remove the primary transform from the output terminals 8 and 9 Indicator 7 power not less than 5 W at a voltage of 50 V.

The use of the invention allows to provide a stable power supply of autonomous automatic measuring devices of low power, located under the ground potential near the wires of high voltage lines, without the use of expensive systems for converting high voltage to low voltage.

Claims (1)

A power take-off system from a three-phase high-voltage transmission line, containing single-circuit supports each with a transverse traverse, on which phase wires of a three-phase line are suspended through high-voltage insulators, a primary converter with output terminals that are connected to the input terminals of the converter-voltage regulator, to the output terminals of which load, characterized in that the primary Converter is made in the form of a flat metal grid lying on the ground and extended along the direction core wire, with a piece of flat multi-wire cable placed on a flat metal mesh that is parallel to the direction of the phase wires, the longitudinal axis of which is removed from the projection line to the ground of the nearest phase wire of the three-phase transmission line by a distance equal to the largest of the distances of the projection of the phase wires onto the plane passing through single-chain supports, with the plane of the length of the flat multi-wire cable parallel to the plane of the earth, one of the ends of each wire of the flat multi-wire cable is connected to a common contact point on the metal grid, and its second end is connected to the terminal, which serves as the first output terminal of the transducer, and the second output terminal of the primary converter is a common contact point on the metal grid.