WO2012173517A1

WO2012173517A1 - Method for melting ice on the wires of a three-phase overhead power transmission line

Info

Publication number: WO2012173517A1
Application number: PCT/RU2012/000358
Authority: WO
Inventors: Роман Николаевич БЕРДНИКОВ; Юрий Александрович ГОРЮШИН; Юрий Александрович ДЕМЕНТЬЕВ; Александр Сергеевич ЗАСЫПКИН; Иван Иванович ЛЕВЧЕНКО; Евгений Иванович САЦУК; Сергей Сергеевич ШОВКОПЛЯС
Original assignee: Открытое Акционерное Общество "Федеральная Сетевая Компания Единой Энергетической Системы" (Оао "Фск Еэс"); Общество С Ограниченной Ответственностью "Тмк-Центр" (Ооо "Тмк-Центр")
Priority date: 2011-06-14
Filing date: 2012-05-05
Publication date: 2012-12-20
Also published as: RU2465702C1

Abstract

The invention relates to the field of electrical energy, and in particular to the melting of ice on three-phase overhead power transmission lines. The technical result of the invention is a reduction in the power consumed and the time taken to melt ice on three-phase overhead power transmission lines without the need for complex converter equipment. Direct current is run through the wire (7) of the master phase of the overhead power line and the two wires (8 and 9) of the other phases, connected in parallel, alternately in consecutive time periods not exceeding 20% of the expected total melting time, wherein each phase of the three-phase overhead power transmission line is used cyclically as the master phase, and the intensity with which the corresponding wire is heated is controlled by adjusting the ratio of the length of the time period during which this phase is used as the master phase to the total length of the cycle. The consecutive time periods are separated by dead time.

Description

The method of melting ice on wires of a three-phase air

power lines

Technical field

The invention relates to the electric power industry, in particular, to ice melting on three-phase overhead power transmission lines (VL).

State of the art

For smelting ice on three-phase overhead power lines, a direct (rectified) current is used, which is generated using rectifier units based on AC to DC converters. Rectifier installations are located in areas with a standard ice wall thickness of 20 mm or more at substations that are connected by overhead lines of different voltage classes, usually 220-500 kV, of different lengths, with different cross-sections of wires and the number of wires in phase. Ice can be melted under different weather conditions - air temperature and wind speed. These differences make it necessary to conduct ice melting with adjustable wire heating capacities, including unequal in the phase wires of one overhead power transmission line, since, as a rule, ice deposits on the leeward and leeward phases of overhead lines are different.

Simultaneous (not alternate) icing in all three phases of overhead lines with independent regulation of the melting current in each phase requires sophisticated converting equipment with several controlled thyristor groups (it can be performed, for example, with installation for each phase of a separate thyristor converter) and therefore has not found wide application.

Known and widely used, the prototype method of melting with direct current of the rectifier installation, with connecting the OHL phase wires according to the “phase-two phases” scheme, in which the current is alternately passed through the main phase wire and the wires of two other phases connected in parallel, and completing the melting ice in the next main phase is connected as the main another phase. Such a melting sequence is used, in particular, in the method [RU 2309522 from 06.24.2006]. In the prototype, ice melting on a three-phase line is performed for three time intervals, and in the second and third intervals, the melting current passes through the wires of those phases at which the ice is already melted in the first and second time intervals, respectively. As a result, the heating energy is used inefficiently, since the phase-free wires of ice are uselessly heated, and accordingly the total (total) melting time increases, during which the overhead line remains out of operation.

Used in the prototype, the regulation of the melting current of a controlled rectifier installation does not eliminate this drawback, since the procedure for melting ice of a three-phase line in three time intervals is preserved - one time interval for each phase.

SUMMARY OF THE INVENTION

The technical result of the invention is the reduction of energy consumption and the reduction of the melting time on the three phases of overhead lines without the use of complex converting equipment for smelting ice.

The subject of the invention is a method of melting ice on the wires of a three-phase overhead line, which consists in the fact that alternately during consecutive time intervals not exceeding 20% of the expected total melting time, direct current is passed through the wire of the main phase of the overhead line and two wires of the other phases connected in parallel, while each phase of the overhead line is cyclically used as the main phase and the heating power of its wire is controlled by changing the ratio the duration of the time interval in which this phase is used as the main, to the total duration of the cycle.

This set of features allows to solve the problem of the invention.

The development of the invention provides for the separation of consecutive time intervals without current pauses.

This makes it possible to further simplify the conversion and switching equipment used for melting.

The implementation of the invention in view of its development

The implementation of the proposed method is illustrated by the structural diagram in figure 1 and time diagrams of currents in the phases of the overhead line in figure 2.

Figure 1 shows a bipolar controlled thyristor rectifier, consisting of a three-phase cathode group 1 and a three-phase anode group 2, a bridge switching device with four thyristor arms - 3,4,5,6, three phases 7,8,9 VL, on the wires of which carry out melting ice; fusion control unit 10, rectifier power supply 1 1 by three-phase alternating voltage.

The method is as follows.

On the side of the overhead line removed from operation, remote from the rectifier (direct current source of melting), the phase wires are short-circuited.

During the first time interval t] (see FIG. 2), thyristors of groups 1, 2 and arms 3 and 4 of the thyristor switching device are turned on with a control angle close to zero. In this case, direct current melting flows through a phase 7 wire, which in this interval is the main one, and two other phases 8 and 9 connected in parallel, and the currents of the corresponding phases are Ι ₇ = Ι, Ι ₈ = 0.5 · Ι, Ι ₉ = 0.5 · Ι, where I is the current in the main phase of the overhead line. At the end of the first time interval, the thyristors of groups 1, 2 and arms 3 and 4 are turned off. After a dead time pause Δΐ = 5 · τ, where t is the decay time constant of the overhead line current (5 <1s), turn on with a control angle close to zero , thyristors of groups 1, 2 and arms 3 and 6 .. During the second time interval t ₂ , the melting current passes through the wire of phase 8, which is the main wire in this interval, and two other phases 7 and 9, connected in parallel, and the currents of the corresponding phases are Ι ₇ = 0.5 · Ι, Ι ₈ = Ι, Ι ₉ = 0.5 · Ι. At the end of the second time interval, the thyristors of group 1, 2 and arms 3 and 6 are turned off. After a dead time pause Δί turn on with a control angle close to zero, the thyristors of groups 1, 2 and arms 4 and 5 .. During the third time interval t ₃ the melting current passes through the wire of phase 9, which is the main one in this interval, and two other phases 7 and 8, connected in parallel, and the currents of the corresponding phases are Ι ₇ = 0.5 · Ι, Ι ₈ = 0.5 · Ι, Ι ₉ = Ι. After the third time interval, through a currentless pause At, the process is cyclically repeated and continues until the ice is melted at all phases of the overhead line. Commands for turning on and off the three-phase thyristor groups and the corresponding arms of the thyristor switching device are provided by the control unit 10. The thyristor converter is powered by a three-phase alternating voltage by a power supply 1 1.

The ice melting time at each phase of the overhead line is determined by the square of the current value

If = I ² · t _x + 0.25 - 1 ² · + 0.25 · / ² · t ₃ ;

/ | = 0.25 - / ² · t _t + I ² · t ₂ + 0.25 · I ² 't ₃ ;

/ | = 0.25 - / ² - t _x + 0.25 · I ² · t ₂ + 1 ² · t ₂ . Percentage of total heating power delivered wire of each phase of VL, determined by the relative length of intervals t ^ t T, where the duration of the cycle T = 1 _g + t ₂ + t ₃ 4- 3 Δϋ, ai = 1, 2, 3.

The duration of the cycle in practice varies from several tens of seconds to several minutes.

The greatest energy savings and the minimum melting time is ensured while melting ice on the wires of all phases of the overhead line.

With the same thickness of the ice wall at all phases of the overhead line, ice melting will occur almost simultaneously at ti _* = £ _{2 *} ^{= and the} relative durations of all intervals, approximately (if we neglect short currentless pauses Δϋ) equal to 1/3.

If the wall thickness of the ice is different on the phases of the overhead line, then for the simultaneous melting of the ice on them set in the control unit 10 intervals duration in accordance with the expressions

_ 1 5 - to _in - to _with _

~ r 1 + k _in + ks

1 -1 + 5 - k _v - k _s

Ϊ ^{2 ~} 3 1 + k ₃ + k _s '

where k ₃₎ k _s are the unevenness coefficients of the currents in the phases of the overhead line, which are determined by the ratio of the ice wall thicknesses taking into account weather conditions - air temperature and wind speed and can be calculated using icing control data obtained, for example, using an automated system [Information system for icing control on overhead power lines / A.F. Dyakov, I.I. Levchenko, A.S. Zasypkin, etc. // Energetik.-2005, JVfel 1, p.20-25].

When melting ice on short lines, the melting current can be reduced to an acceptable value by increasing the duration of dead time pauses At (figure 2).

To control each thyristor shown in FIG. 1, a circuit known, for example, from [Handbook of converter technology. Ed. I.M. Chizhenko. K., "Techshka", 1978], which provides the inclusion of a thyristor with an angle of control close to zero, and turning off the thyristor in a dead time.

The reduction in energy consumption and the reduction of ice melting time in relation to the prototype is practically manifested in cases where the total cycle time T does not exceed 20% of the total expected (according to the icing control system) melting time, i.e. the expected ice melting time is divided into at least five cycles. Moreover, the duration of one cycle is usually 5-10 minutes.

Claims

Claim

1. The method of melting ice on the wires of a three-phase overhead transmission line, which consists in the fact that alternately for successive time intervals not exceeding 20% of the expected total melting time, direct current is passed through the wire of the main phase of the overhead line and two wires of other phases connected in parallel, in this case, each phase of the overhead line is cyclically used as the main phase and the heating power of its wire is controlled by changing the ratio of the duration of the time interval in which this phase is used as TBE main, to the total cycle time.

2. The method according to p. 1, in which consecutive time intervals are separated by dead time pauses.