RU2312441C2 - Power transmission line - Google Patents

Abstract

FIELD: high-voltage engineering; power transmission lines.

SUBSTANCE: proposed power transmission line has at least one conductor, one supporting structure, and lightning protection device insulated from supporting structure by means of insulating member and connected to ground electrode driven in soil. Ground electrode has no metal contact with supporting structure. Closest distance D between edge of supporting structure and that of ground electrode driven into soil is found from expression 0.2 cm < D < 50 m. Lightning protection device can be made in the form of lightning arrester or nonlinear surge limiter, or in the form of ground wire.

EFFECT: improved design of power transmission line lightning protection gear.

8 cl, 3 dwg

Description

Technical field

The present invention relates to the field of high-voltage technology, and more specifically to power lines.

State of the art

Known high-voltage power lines (transmission lines), as a rule, include a power wire fixed to supports by means of insulation elements (insulators), as well as lightning protection devices, i.e. devices to limit overvoltages arising in the line when lightning enters it. A line may contain several wires, for example, if the line is multi-phase. The supports are usually grounded, but there are also power lines with ungrounded supports.

The most common lightning protection device is a lightning protection cable, which is suspended on a support column above power wires. In the event of a lightning strike in the power line, the lightning channel enters the lightning-protective cable and the lightning current through the support body (with a conductive, for example, metal, support stand) flows to the ground.

In the case of an insulating support, for example wooden, to drain the lightning current along the body of the support, a metal run (wire) is laid, which is connected to a special ground electrode. The grounding resistance of the support or ground electrode system must be sufficiently small, on the order of 10 Ohms, so that it does not create a large voltage drop due to the flow of lightning current.

In the absence of a lightning protection cable, lightning arresters of various types (for example, tubular or long-spark) or non-linear surge arresters (surge arresters) are also used as lightning protection devices. The arrester or surge arrester is connected with one clip to the wire, and with the other - to the transmission line support, which must be well grounded, i.e. have a low value of grounding resistance. In some cases, a spark gap or arrester is connected to the wire through a spark gap, which, under the influence of overvoltage, breaks through, and the channel of the resulting spark connects the gap of the spark gap to the power line wire.

If the grounding resistance is not small enough, when a lightning current flows, a large voltage drop occurs on it, i.e. the potential of the support increases and back overlapping from the support body to the wire may occur.

The body part of the conductive support, buried in the ground, is a natural grounding. In the case of well-conducting soils, the necessary grounding resistance is provided without additional measures.

In the case of poorly conductive soils, various types of grounding conductors are used to reduce the grounding resistance of the support, which are metal-connected to the support body.

Known, for example, is a power line with an earthing switch made in the form of beams of metal strips laid in the ground and diverging from the support in different directions ("High Voltage Technique". Edited by DV Razevig. M .: "Energy", 1976, p. 283). The disadvantage of this power line is the high cost of the ground electrode. In addition, with poorly conducting, for example rocky, soils, it is not possible to provide the required low grounding resistance.

Also known is a power line with grounding conductors made of one or more rod electrodes placed vertically in the ground ("High Voltage Technique". Edited by DV Razevig. M .: "Energy", 1976, p. 283). These electrodes are metallic interconnected, as well as with the support body or conductive descent and further with lightning protection devices (lightning protection cable and / or arresters).

This line is the closest to the claimed and adopted as a prototype. Unfortunately, with poorly conducting soils, this line also does not have the necessary low value of grounding resistance and, accordingly, is not lightning proof enough, and therefore not reliable enough.

SUMMARY OF THE INVENTION

The objective of the present invention is to provide a reliable and low cost in the construction and operation of power lines.

The technical result is to increase reliability by increasing the lightning resistance of the line.

The objective of the invention is solved in that in a power line including at least one wire, at least one support and a lightning protection device, isolated from the support using an insulating element and connected to an earthing switch located in the ground, and according to the invention, said ground electrode is metallic not connected to the body of the support, and the shortest distance from the edge of the support to the edge of the ground electrode D is determined by the ratio: 0.2 m <D <50 m.

Brief Description of the Drawings

The invention is illustrated by drawings, which depict:

Figure 1 - diagram of a power line with a surge arrester connected to a wire and a freestanding ground electrode;

Figure 2 is a diagram of a power line with a ground wire located on an insulating stand and connected to a freestanding ground electrode;

Figure 3 is the same as Figure 2, but with mechanical fastening of the cable to the support using tension insulators.

Information confirming the possibility of carrying out the invention

Figure 1 shows the power line, which contains the support 1, the wires of phase A 2, phase B 3 and phase C 4 power lines attached to this support 1, and a string of insulators phase A 5, phase B 6, phase C 7 of these wires 2 , 3, 4 power lines, respectively, from the indicated support 1. An arrester 8 is connected to the phase A 2 wire using one of its terminals. The second arrester terminal 8 is connected to the ground electrode 9.

When lightning strikes a phase A 2 wire, an arrester 8 is triggered and a lightning overvoltage current flows through an earthing switch 9, having an earth resistance R ₃ , to ground. In the case of a metal connection of the ground electrode to the support, as is done in the prototype, the potential of the support is equal to the potential of the ground electrode. At large values of the soil resistivity, for example, on rocky soils, the voltage drop from the lightning overvoltage current on the ground resistance or, equivalently, the potential of the support can become very significant. This can lead to the so-called reverse overlap, i.e. to overlap from the support 1 to the wire of the unaffected phase, for example, phase B 3.

In the case of a power line according to the invention, i.e. when an earthing switch is not metallic connected to the support, the potential of the support increases significantly less. Indeed, due to the spreading of current in the earth around the ground electrode, a potential distribution is created that decreases with distance from the earth electrode. A conductive support located at some distance from the ground electrode acquires the potential U _OP , which can be significantly less than the potential of the ground electrode U _З. Mathematically, this ratio can be expressed by the formula U _ОП = U _З к _з , where к _з <1 is the coupling coefficient over the earth. Accordingly, in the case of an earthing switch, which is not metallic connected to the support, the likelihood of the back-up of the garland of phase B 6 insulators decreases and the lightning resistance of the power line increases.

It should be noted, however, that in the case of a metal connection of the ground electrode to the support, as in the prototype, when the arrester 8 is triggered, practically no voltage is applied to the string of phase A 5 insulators, i.e. the garland of phase A 5 insulators cannot overlap.

In the event that the ground electrode is not metallic attached to the support, after the arrester 8 is activated, some voltage remains applied to the string of phase A 5 insulators. The analysis shows that at the same time, the lowest voltage values on the garlands of insulators of phase A 5 and phase B 6 are achieved with the value of the ground coupling coefficient k _s , determined by the formula:

where k _B is the coupling coefficient between the wires through the air.

The analysis also shows that in this case the voltage across the string of insulators of phase A 5 and phase B 6 insulators of the power line according to the invention is exactly two times less than the voltage across the string of insulators of phase B of the prototype line. Thus, the level of lightning resistance of an overhead line according to the invention with a freestanding earthing switch at an optimal ground coupling coefficient is two times higher than with a traditional grounding of a support with the same value of grounding resistance.

The ground coupling coefficient depends on the shape of the ground electrode and the grounded part of the support, the soil resistivity, as well as the magnitude of the lightning overcurrent flowing current, which determines the intensity of spark formation around the ground electrode. The analysis shows that the optimal location of the ground electrode, determined by the shortest distance between the edge of the ground electrode and the edge of the grounded part of the support D, lies in the range of 0.2 m <D <50 m depending on the specified parameters.

Consider, as an example, a 35 kV overhead line on a reinforced concrete support. The depth of the support strut in the ground is 3 m. As a ground electrode, we consider a vertically arranged metal rod of the same length. Connection between the wires through the air factor is approximately to _a = 0.4, the optimal value of the coupling coefficient between the earth electrode and the support on the ground in accordance with the

To ensure the indicated value of the ground coupling coefficient at a lightning current of 40 kA in sandy soil, a distance between the ground electrode and the support is approximately 3.5 m, and in clay soil - 0.5 m.

Figure 2 shows the power line, which contains the support 1, the wires of phase A 2, phase B 3 and phase C 4 power lines attached to this support 1, and a string of insulators phase A 5, phase B 6, phase C 7 of these wires 2 , 3, 4 power lines, respectively, from the indicated support 1. At the top of the support 1, an insulating stand 10 is installed, to which the lightning protection cable is attached 11. The cable 11 is connected to the ground electrode 9 located in the ground with a metal trigger 12. When lightning strikes the cable 11, lightning current overvoltage flows along the metal trigger 12 through the resistance R ₃ s ground switch 9 to the ground. If the lightning resistor were conductive, as in the prototype, or the ground electrode was metal connected to the support (which is equivalent in the electrical sense), a large voltage drop is created due to the flow of a large lightning current on the support ground resistance, i.e. support potential can become very significant. This can lead to the so-called reverse overlap, i.e. to overlap from the support 1 to the wire of one of the phases, for example phase B 3.

In the case of a power line according to the invention, i.e. when an earthing switch is not metallic connected to the support, the potential of the support increases significantly less. Indeed, due to the spreading of current in the earth around the ground electrode, a potential distribution is created that decreases with distance from the earth electrode. A conductive support located at some distance from the ground electrode acquires the potential U _OP , which can be significantly less than the potential of the ground electrode U _З. Accordingly, in the case of an earthing switch, which is not metallic connected to the support, the probability of reverse overlapping of the strings of insulators 5, 6, 7 decreases and the lightning resistance of the power line increases.

To reduce losses in the cable at operating voltage arising from the flow of currents induced in the cable-to-ground loop, the ground electrode 9 can be connected to the cable 11 using a conductive descent and a spark gap connected in series with it (it is not shown in FIG. 2), mounted on a suspended insulator, as is usually done when installing lightning protection cables on metal lightning fasteners.

Figure 3 shows another variant of the line with an insulating stand according to the invention. To reduce the mechanical load on the insulating rack 10, the mechanical fastening of the cable 11 to the support 1 is carried out using tension insulators 13, which perceive the main mechanical load. The insulators 13 can be made, for example, of polymeric materials.

To increase the impulse strength of the insulation rack, it can be made with a semiconducting coating, for example, from semiconducting polyethylene with a specific volume resistance of 10 ³ -10 ⁵ Ohm · m.

The options and modifications of the power line provided in the present description of the invention are given only to explain their device and operating principles. Specialists in the art should understand that there may be deviations from the above examples, which are also covered by the claims.

Claims (8)

1. Power line, comprising at least one wire, at least one support and a lightning protection device, isolated from the support by means of an insulating element and connected to an earthing switch located in the ground, characterized in that said earthing switch is not metal connected to the body supports, and the shortest distance from the edge of the support to the edge of the ground electrode in the soil D is determined by the ratio of 0.2 m <D <50 m. 2. The power line according to claim 1, characterized in that the lightning protection device is made in the form of an arrester, with one clip attached to a wire isolated from the support using an insulator or a string of insulators, and the other clip to an earthing switch. 3. The power line according to claim 1, characterized in that the lightning protection device is made in the form of a nonlinear surge suppressor, with one clip attached to a wire isolated from the support using an insulator or a string of insulators, and with the other clip to an earthing switch. 4. The power line according to claim 2 or 3, characterized in that the spark gap or non-linear surge suppressor is connected to the wire through the spark gap. 5. The power line according to claim 1, characterized in that the lightning protection device is made in the form of a lightning protection cable, and as an insulating element, an insulating stand installed on top of the support is used. 6. The power line according to claim 5, characterized in that the lightning protection cable is connected to the ground electrode through a spark gap. 7. The power line according to claim 5, characterized in that the insulating stand is made with a semi-conductive coating. 8. The power line according to claim 5, characterized in that the mechanical fastening of the cable to the support is carried out using tension insulators.

Images