RU39017U1 - DEVICE FOR HUNGER MELTING ON WIRES AND DARK-PROTECTED CABLE OF ELECTRIC TRANSMISSION AIR-LINES - Google Patents

Abstract

Device for melting ice on wires and lightning protection cables of an overhead power line This ensures equalization of currents in all sections of the lightning protection cable between its grounding points on poles having different grounding resistances along the length of the power line. This result is achieved by compensating for the voltage drop across the ground electrodes at the ends of the cable with secondary voltage generated by passive power converters of the wire current into voltage. Variants of converter circuits and their inclusion are given.

Description

The utility model relates to the electric power industry and can be used for melting ice on wires and a lightning protection cable of an overhead power transmission line.

A device for the simultaneous melting of ice on wires and cables [MU 34-70-027-82. Guidelines for smelting ice with alternating current. M., 1983, Figs. 25 and 26]. This device contains an AC or DC power source connected to the ground conductor of the first ground electrode and to interconnected wires at the first end of the overhead power line, at the second end of which the wires are also interconnected and are connected by a grounding conductor to the second ground electrode, and a lightning protection cable insulated throughout the melting section and connected at one end to the same power source, and the second to the grounding conductor of the third ground electrode.

The disadvantage of the above device is the need to use insulators shunted by spark gaps to isolate the cable from the body of the support throughout the melting area, which complicates the device for melting ice and reduces the effectiveness of the lightning protection cable in the lightning season. It cannot be used with a multiply grounded lightning protection cable.

A device for the simultaneous melting of ice on wires and inducted current on a multiply grounded lightning protection cable, selected as a prototype [Balyberdin L. L., Galanov V. I., Kraichik Yu.S. etc. Induction ice melting on lightning protection cables of overhead power lines. -Electric stations, 2002, No. 1, p.31-37]. This device contains an AC power source connected to the grounding conductor of the first ground electrode and to interconnected wires at the first end of the overhead power line; a power line, at the second end of which the wires are also interconnected and connected by a grounding conductor to the second ground electrode, and repeatedly grounding lightning protection cable connected at the ends by grounding conductors to the third and fourth grounding conductors.In this device, due to electromagnetic coupling between the “wire - emlya "and" wire-to-ground "in the latter induces a current and heat is needed to melt ice on the cable, the cable insulation from the supports easier, increases the efficiency of grounding wire in the thunderstorm season.

The disadvantage of this device is the inequality of the currents on the sections of the lightning protection cable between the points of its grounding on poles having different grounding resistances along the length of the overhead line

power transmission, if the grounding conductors at the ends of the lightning protection cable are not ideal, i.e. have a resistance other than zero, which always takes place. The inequality of currents in sections of a lightning protection cable reduces the efficiency of melting and complicates the control of melting ice on it.

The utility model is aimed at achieving a technical result, which consists in equalizing currents in sections of a lightning protection cable between its grounding points on poles having different grounding resistances along the length of the overhead power line.

To achieve this technical result, a device for melting ice on wires and a lightning protection cable of an overhead power line, containing an AC power source connected to the ground conductor of the first ground electrode and to interconnected wires at the first end of the overhead power line, at the second end of which the wires are also interconnected and connected by a grounding conductor to the second grounding conductor, and a multiply grounded lightning protection cable connected at the ends by grounding by the conductors at the first end to the third, and at the second end to the fourth ground electrode, two passive power current to voltage converters with complex conversion factors having inductive and active components are additionally inserted at the ends of the lightning protection cable, the first converter is connected in series to the ground conductor circuit by a primary circuit the first ground electrode, and the secondary circuit is connected in series to the grounding conductor circuit of the third ground electrode, the second converter of the primary circuit I drink is connected in series to the grounding conductor circuit of the second ground electrode, and a secondary circuit is connected in series to the grounding conductor circuit of the fourth ground electrode.

The technical result is achieved by compensating for voltage drops from the induced current of the lightning protection cable in the resistances of the third and fourth earthing switches by the secondary voltages of passive power converters, the primary circuits of which are connected to the current passing through the wires during ice melting. This ensures a voltage close to zero with respect to the earth at the ends of the lightning protection cable, i.e. grounding conductors at the ends of the lightning protection cable are close to ideal, which, as you know, ensures equalization of currents in all parts of the lightning protection cable between its ground points and poles having different grounding resistances along the length of the overhead power line.

The utility model has two developments characterizing two of several possible particular forms of realization of a passive power converter of current to voltage. The first form of implementation having

inductive conversion coefficient, made in the form of a double winding reactor; the second form of implementation, which has an active conversion coefficient, is the total current spreading resistance of two closely spaced grounding conductors: the first and third, second and fourth.

Another development provides the implementation of a useful model if the ground electrode of a lightning protection cable (third or fourth) is located at a large distance from the grounding wires (first or second), when only part of the overhead power transmission line is protected by a lightning protection cable, and that the primary circuit of the corresponding passive power supply the current-to-voltage converter is not included on the current of the grounding conductor of the first or second ground electrode, but on the equal sum of the currents of the wires using current transformers.

In the drawing of Fig. 1, a diagram of a device with a lightning protection cable along the entire length of an overhead power transmission line is shown, in the drawing of Fig. 2 - with a lightning protection cable for a part of the length of an overhead power transmission line, when the grounding wires and a lightning protection cable at the second end are removed from each other.

A device for melting ice on wires and a lightning protection cable of an overhead power transmission line (Fig. 1) contains an AC power source 1 connected to the grounding conductor 2 of the first ground electrode, represented on the circuit by grounding resistances 3 and 4, where 4 is the total current spreading resistance of the first and third grounding conductors, through the primary winding of a double-winding reactor 5, which is part of the first passive power converter of current to voltage 6. The second output of power source 1 is connected to the connected These are wires 7 at the first end of the overhead power transmission line, at the second end of which wires 7 are also interconnected and connected by grounding conductor 8 to the second ground electrode, shown in the diagram by grounding resistances 9 and 10, where 10 is the total current spreading resistance of the second and fourth grounding conductors , through the primary winding of a two-winding reactor 11, which is part of the second passive power converter of the current to voltage 12. Lightning protection cable 13 can be repeatedly grounded through grounding supports 14, 15 and others, and at the ends is connected by grounding conductors 16 and 17 to the third grounding conductor, represented by resistances 18 and 4, and to the fourth grounding conductor, represented by resistances 19 and 10, through the secondary windings of double-winding reactors 5 and 11. The diagram also shows the line the surface of the earth 20 and the line of zero potential 21.

Passive power converters of current to voltage 6 and 12 are made according to the same type of schemes and consist of double-winding reactors 5 and 11 and common resistance to current spreading of two closely spaced

grounding conductors: 4 at the first and third grounding conductors and 10 at the second and fourth grounding conductors. The possibility of representing two closely spaced grounding conductors as an equivalent circuit in the form of a three-beam resistance star is shown in the article [Levchenko II, Zasypkin AS, Loganchuk LM On the use of an external earthing switch for melting ice on high-voltage lines with direct current. - Electric stations, 2001, No. 4, p.25-28].

The device, the circuit of which is shown in Fig. 2, differs from the one described above by the absence of a general resistance to current spreading 10 in Fig. 1 for the earthing switches of the second 9 and the fourth 19 because of their significant distance from each other, as well as by another circuit of the second passive power converter current to voltage 12, the primary circuit of which is connected to current transformers 22, and the complex conversion coefficient is realized by a power transreactor 23 loaded on a power resistor 24.

The possibility of obtaining the above technical result is confirmed by the following explanations. To compensate for the voltage drop in the ground electrode, to which the end of the lightning protection cable is connected, using a passive power current-to-voltage converter, for example, presented in figure 1, it is necessary to ensure equality

i _p (jx _m + R _m ) = i _t (jx ₂ + R ₂ ), (1)

where i _p , i _t - currents in wires 7 and cable 13;

jx _m + R _{m is the} complex conversion coefficient of the converter;

jx _m , jx _{2 are the} inductance of a two-winding reactor:

the mutual between the primary and secondary windings and its own secondary winding;

R _m - the total resistance of 4 or 10 two closely spaced earthing switches;

R ₂ is the total resistance of the cable grounding circuit.

The relation between the currents of wires i _p and the induced current in the cable i _t is known for perfect grounding of the ends of the cable or, as proposed, when compensating for the voltage drop in both grounding conductors at the ends of the cable:

(2)

where Z _tz - the resistance of the circuit "cable-to-ground";

Z _m - the mutual resistance between the contours of the "wire-to-ground" and "cable-to-ground".

Substituting (2) into (1), we obtain two design relationships for determining the inductive and active parameters of a passive power current-to-voltage converter, which ensures equalization of currents in all sections of the lightning protection cable between its grounding points on supports having different resistances 14, 15, etc. ., along the length of the overhead power line.

Claims (4)

1. Device for melting ice on wires and a lightning protection cable of an overhead power transmission line, comprising an AC power source connected to the grounding conductor of the first ground electrode and to interconnected wires at the first end of the overhead power transmission line, at the second end of which the wires are also interconnected and connected by a grounding conductor to the second grounding conductor, and a multiply grounded lightning protection cable connected at the ends by grounding conductors at the first end to the third, and at the second end to the fourth earthing switch, characterized in that two passive power current-to-voltage converters with complex conversion factors having inductive and active components are additionally inserted at the ends of the lightning protection cable into it, the first converter is connected in series to the grounding conductor of the first earthing switch by a primary circuit, and the secondary circuit is connected in series to the grounding conductor circuit of the third ground electrode, the second converter is connected by the primary circuit after chain sequences in the grounding conductor of the second earthing and a secondary circuit is connected in series to the circuit of the fourth grounding conductor of the earthing. 2. The device according to claim 1, characterized in that the passive power current to voltage converter having an inductive conversion coefficient is made in the form of a double winding reactor. 3. The device according to claim 1, characterized in that the passive power converter of the current to voltage, having an active conversion coefficient, is the total resistance to current spreading of two closely spaced grounding conductors: the first and third, second and fourth. 4. The device according to claim 1, characterized in that the primary circuit of the first or second power converter is connected via current transformers in the wires of the overhead power line for the sum of the currents of the wires equal to the current of the grounding conductor of the first or second ground electrode.