RU2376692C1 - Combined plant for glase ice and reactive power compensation - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention relates to electric engineering and may be used on electric substations. Combined plant for glase ice melting and reactive power compensation contains feed transformer, the first high-voltage disconnecting link and the first three-phase reactor. The second three-phase reactor is coupled with the above first reactor in serial connection and shunted by the second high-voltage disconnecting link. The high-voltage bridge-converter is made up from completely controlled hardware and bypass diodes connected in parallel. A capacitor bank is available at direct current output of the high-voltage bridge converter. Each pole output of the above capacitor bank is coupled with single-phase disconnecting link. Plant control system is synchronised with the network through separate resonance transformer. The first and the second control system outputs are connected to the first and second disconnecting link respectively. The third control system output is connected to the high-voltage bridge converter. Control system is implemented so that frequency and pulse-width modulation factor can be changed in the completely controlled hardware of the high-voltage bridge converter.

EFFECT: reduced switching of power equipment when melting mode is switched over to compensation mode and increased fast response in compensation mode.

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Description

Technical field

The invention relates to the field of electrical engineering and can be used in power substations, where it is necessary to ensure icing on wires or isolated from supports of lightning protection cables of overhead power lines (OHL) of power transmission lines, as well as to provide the level of required voltage in load nodes and control of reactive power flows.

State of the art

Currently, diode installations for smelting ice on overhead lines with direct current are widespread [1]. Despite the apparent simplicity, the operation of uncontrolled (diode) installations raises a number of difficulties: inrush current when turned on, which can lead to an accident; the impossibility of changing the melting current, which does not allow the use of the same installation for melting on lines of various parameters or on cables; the impossibility of using different melting circuits ("snake", "two wires - wire", etc.) on the same line, etc.

Thyristor installations for melting ice [2], devoid of the above disadvantages, are also known. However, both the installations [1] and [2] have a significant common drawback: they are used for a very limited time during the year. There may be long periods when the units do not turn on at all.

A proposal is known for a combined installation for smelting ice and reactive power compensation [3], for the implementation of which it is necessary to understaff the static reactive power compensator (STK) with seven three-phase high-voltage (full line voltage) disconnectors. In addition, the overhead line on which it is supposed to melt ice and the overhead line to which the STK is supposed to be connected are, as a rule, not the same overhead line. Therefore, it is required to install additional power equipment at the substation for the physical implementation of the circuits according to [3]. As a result, the cost of equipment according to [3] and the total cost of a separate STK and a separate thyristor installation for smelting ice are comparable, so the economic effect is practically not achieved. We note in addition that the STK as a reactive power compensation unit from the modern point of view has several disadvantages: it is not compact, characterized by low speed, and cannot be used either as a phase-shifting device, or as a flicker corrector, or as an active filter.

Also known is a combined installation for melting ice on wires and cables of overhead power lines with a reactive power compensation function, comprising a supply transformer with a first high-voltage disconnector at the output, in series with which a first three-phase reactor and a high-voltage bridge converter with a DC capacitor battery are connected, to the output of each from the poles of which are connected via a single-phase disconnector, and a control system, one of the outputs of which is connected to high-voltage m bridge converter [4]. This combined installation is accepted by us as a prototype. It is more mobile in operation than the device according to [3], but also does not differ in high speed in the mode of reactive power compensation.

SUMMARY OF THE INVENTION

The objective of the invention is the creation of a high-voltage installation for melting ice on wires and cables of overhead power lines (VL) of power lines with a reactive power compensation function, in which the transfer from the melting mode to the compensation mode is carried out without significant switching of power equipment, and the compensation mode provides high speed. The solution to this problem provides savings in capital costs by reducing the total amount of equipment installed in the substation, and increasing the level of equipment availability and expanding its functions.

The essence of the invention lies in the fact that the combined installation for melting ice and reactive power compensation contains a supply transformer with a first high-voltage disconnector at the output, in series with which a first three-phase reactor and a high-voltage bridge converter with a DC capacitor bank are connected, to the output of each of which poles are connected by a single-phase disconnector, and a control system, one of the outputs of which is connected to a high-voltage bridge converter, which The first one is made on assemblies of fully controllable devices with reverse diodes connected in parallel; a second three-phase reactor is connected in series with the first three-phase reactor, in parallel with which a second high-voltage disconnector is connected, the control system is synchronized with the network from a separate resonant transformer, and two other outputs of the control system are connected to the first and second high-voltage disconnectors, and the control system is configured to change the frequency and PWM modulation coefficient of operation of fully controllable devices of a high-voltage bridge converter.

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

The implementation of the invention

The invention is illustrated by the scheme of a combined installation for melting ice and reactive power compensation, shown in the drawing.

The installation comprises a supply transformer 1 with a first high-voltage disconnector 2 at the output, in series with which the first three-phase reactor 3 and a high-voltage bridge converter 4 with a DC capacitor bank 5 are connected, to the output of each of the poles of which a single-phase disconnector 6 and 7 is connected, and a control system 8, one of the outputs of which is connected to a high-voltage bridge converter 4, which is made on assemblies 9-14 from fully controllable devices with reverse diodes connected in parallel; in series with the first three-phase reactor 3, a second three-phase reactor 15 is connected, in parallel with which a second high-voltage disconnector 16 is connected, the control system 8 is synchronized with the network through a separate resonant transformer 17, and two other outputs of the control system 8 are connected to the first 3 and second 16 high-voltage disconnectors, and control system 8 is configured to change the frequency and modulation factor of the PWM operation of fully controllable devices from assemblies 9-14 of a high voltage bridge converter spruce 4.

The scheme of the combined installation is switched to the mode of melting with direct current of ice on the wires or cables of the overhead line when the single-phase disconnectors 6 and 7 are closed and shorted by the closure of the second high-voltage disconnector 16 to the second three-phase reactor 15. In this case, the overhead line on which it is necessary to melt the ice is connected to the output of the high-voltage converter bridge 4 and is the load. The controllability of the converter is achieved by connecting various fully controllable devices from assemblies 9-14. For example, when current flows into the load through the diodes of assemblies 13 and 10, a fully controllable device from assembly 9 or from assembly 14 is connected in the PWM mode. In this case, a two-phase short circuit 9-10 or 13-14 is formed for a short time, the load is bypassed, thereby regulating the current in it. The second three-phase reactor 15 is shorted so as not to limit the maximum current in the load when current flows only through the diodes. At the same time, when a current flows through a short circuit in the absence of a second three-phase reactor 15, the current rise rate in a fully controlled device is high, and it is necessary to interrupt this current before it reaches a dangerous value for a fully controlled device, which is achieved by appropriate frequency selection and the PWM modulation coefficient, the parameters of which are predefined in the control system 8. In this case, the control system 8 gives an impulse to lock a fully controlled device after a time less neck than is required in reactive power compensation mode, when both three-phase reactors - both 3 and 15 - are connected to the circuit. The DC capacitor bank 5 has a significant capacity and smoothes the ripple current in the load.

The installation diagram for operating in reactive power compensation mode is generated by a signal from control system 8 by opening keys 16, 6 and 7. At the same time, a high-voltage bridge converter 4 is connected to the network through the supply transformer 1 and both three-phase reactors 3 and 15 on fully assembled assemblies devices with parallel connected reverse diodes and a DC capacitor bank 5 at the output. The presence of significant inductance, added by introducing the reactor 15, together with the high-voltage bridge converter 4 forms a high-speed reactive power compensator, similar in design and function to STATCOM [5] and possessing all its advantages: high speed, multifunctionality, compactness. In the control system 8, when the device is operated, algorithms known for STATCOM are used as a compensator [5], so that the device can operate both in the consumption mode and in the output of reactive power.

As can be seen, the transfer of the installation from the ice melting mode to the reactive power compensation mode is achieved by switching only three disconnectors.

Thus, the goal - the creation of a high-voltage installation for melting ice on wires and cables of overhead power lines with a reactive power compensation function, in which the transfer from the melting mode to the compensation mode is carried out without significant power equipment switching - has been achieved.

Information sources

1. Levchenko V.I., Zasypkin A.S., Alliluyev A.A., Satsuk E.I. Diagnostics, reconstruction and operation of overhead power lines in icy areas. - M.: Publishing House MPEI, 2007

2. RF patent No. 2207746, class. H05K 7/10, G12B 15/02. Container type conversion plant / L.L. Balyberdin, M.K. Gurevich, M.A. Kozlova, Yu.A. Shershnev. Publ. BI 06/27/2003.

3. RF patent No. 2316867, cl. H02G 7/16, H02J 3/18. Combined installation for ice melting and reactive power compensation / R.A.Dainovsky, N.G. Lozinova, M.I. Mazurov. Publ. BI No. 4 of 02/10/2008.

4. Colin Davidson. AREVA T&D (INNOVATION & PRACTICES), # 2 December 2007, p. 3438.

5. Kochkin V.I., Nechaev O.P. The use of static reactive power compensators in electrical networks of power systems and enterprises. M .: Publishing house "NTs ENAS", 2000

Claims (1)

A combined installation for melting ice and reactive power compensation, comprising a supply transformer with a first high-voltage disconnector at the output, in series with which the first three-phase reactor and a high-voltage bridge converter with a DC capacitor bank are connected, to the output of each of the poles of which a single-phase disconnector is connected, and a system control, one of the outputs of which is connected to a high-voltage bridge converter, characterized in that the high-voltage bridge the converter is made up of assemblies of fully controllable devices with reverse diodes connected in parallel, a second three-phase reactor is connected in series with the first three-phase reactor, a second high-voltage disconnector is connected in parallel, the control system is synchronized with the network from a separate resonant transformer, and two other outputs of the control system are connected to the first and the second high-voltage disconnector, and the control system is configured to change the frequency and coefficient m modulation of PWM operation is fully controlled appliances high-voltage bridge converter.