RU2248077C2 - Method for remote protection of power transmission line - Google Patents

Abstract

FIELD: relay protection and automatic control of power systems.

SUBSTANCE: use is made of group of main and additional reactance relays installed at near and distant ends of power transmission line range under protection. Points of installation of protective gear are hypothetical points of line faults. Components of currents and sums of preceding components of voltages critical for same point of hypothetical fault assumed as currents and voltages of hypothetical ground faults are supplied to inputs of main and additional reactance relays. All groups of reactance relays installed at near or distant end of protected range (or arbitrary number of groups at any point of mentioned range) incorporating three single-phase and three interphase reactance relays constitute separate groups of final relays for each kind of fault including respective groups of relays for near and distant ends of protected range.

EFFECT: enhanced sensitivity of protective gear.

4 cl, 7 dwg

Description

The invention relates to electrical engineering and the electric power industry, in particular to relay protection of power transmission lines based on a remote principle.

Relay protection uses a variety of power line information. Input values deliver current line status information both at the moment and in the previous mode. In addition, there is a priori information on the structure and parameters, on the basis of which a protected line model can be built.

Existing methods of relay protection do not have the ability to make full use of all available information about the protected object. Moreover, a similar task was not previously set. Nevertheless, there is a class of three-phase (multiphase) relays in which three voltages and three currents are measured, measured on one side of the line [1]. But these relays do not solve the problem of optimal use of information and are not able to perceive additional information, for example, about the previous mode.

Later, distance protection methods were proposed that are free from this drawback [3, 4]. They are based on the use of power transmission models. The model, in turn, is based on a priori information about the protected line. Measured currents and voltages are converted using the pre-built line model into currents and fault voltages, assumed in some fixed, predetermined places on the line. The converted values of each prospective fault location are supplied to the corresponding resistance relays.

This method is effective in terms of combining information, but not effective enough in its use. The fact is that the resistance relays, each switched on the converted current and voltage, corresponding to one of the places of the alleged short circuits, act independently of each other and each has a unique response characteristic. It is impossible to select the characteristics so that the protection sensitivity rises to the level of recognition of short circuits [5].

The purpose of the invention is to increase the sensitivity of distance protection. It is achieved by duplication and the special inclusion of a resistance relay. To the main relays present in the prototype, additional relays similar to them are connected, and the place of the individual relays is occupied by groups of similar relays. Each of these groups is included in the same quantities, i.e. there is no external difference between the relays of the same group. The difference comes down only to the response characteristics. In addition to similar relay groups, there are also executive relay groups. The structure of one group of executive relays can include only one of the similar relays. The output signals of all relays of the same executive group are combined by the logical operation AND, and the outputs of different executive groups create an output signal of distance protection according to the OR scheme.

The following claims are set forth in additional claims. It is proposed to choose two fixed places for the alleged damage to the line: the first at the beginning, and the second at the end of the protected zone. This means that the closure is assumed once - at the beginning of the zone, and the second time - at the end.

In addition, it is proposed to separately convert the previous and emergency components of the measured currents and voltages into the corresponding components of currents and voltages in the alleged damage sites, and emergency components of the currents are taken as the currents of the alleged faults, and the sum of the components is taken as the voltage of the alleged faults.

Finally, the approach to compiling groups of similar relays is specified. Each place of the proposed circuit is associated with six groups of similar resistance relays, of which three are phase and three are interphase. Composing then the groups of executive relays, they designate their own group for each type of circuit. Representatives of the corresponding groups of similar relay of phase channels of the beginning and end of the zone are introduced into the group of executive relays of protection against single-phase circuit; representatives of groups of similar relays of this interphase channel are introduced into the group of protection against interphase closure. There remains protection against a two-phase earth fault, where the relays of three damaged channels are activated at once - two phase and one interphase.

Figure 1 shows an arbitrary location of the alleged circuit fault in the power line, figure 2 shows the converter of the measured values into the magnitude of the proposed circuit, figure 3 shows two places of the proposed circuit faults adopted in the proposed method, figure 4 shows the structural diagram of the conversion measured values and their supply to the resistance relay, figure 3 is the simplest example of the implementation of the proposed method for protecting the line from single-phase or interphase faults, figure 6 is a modification of the method and for protection against a two-phase earth fault and in Fig. 7, the characteristics of two groups of similar resistance relays.

напряжений

задается моделью 1 линии электропередачи. В результате формируются токи

(x) и напряжения

(x) места предполагаемого замыкания. Тем самым совершается переход от места наблюдения 2, где x=0, в место предполагаемого замыкания 3, из которого отходят поперечные ветви предполагаемого замыкания 4. Преобразованные величины

(x),

(x) подают на реле сопротивления 5, которым таким образом отводится место в начале ветвей предполагаемого замыкания. Модель электропередачи выполняет при этом роль преобразователя 6.In the proposed method, the conversion algorithm of the measured currents

stresses

defined by power line model 1. As a result, currents are formed

(x) and voltage

(x) the location of the proposed circuit. Thus, a transition is made from the observation point 2, where x = 0, to the place of the proposed closure 3, from which the transverse branches of the proposed closure 4 depart.

(x)

(x) served on the resistance relay 5, which thus allocated a place at the beginning of the branches of the proposed circuit. The power transmission model performs the role of the transducer 6.

(0) и

(l).Places of the proposed closure can be any number. In this case, it is proposed to limit ourselves to two: place 2 at the beginning of the zone and place 7 at the end of the zone. Accordingly, the resistance relays 8 and 9 of the initial and final branches of the alleged damage 10 and 11 will differ. Relays 8 and 9 respond to the values

(0) and

(l).

Each place of the alleged circuit in a three-phase power transmission is associated with six resistance relays 12-17. Phase relays 12-14 respond to values

and the relay of 15-17 linear channels - by

The linear current generator is shown in the form of a current transformer 18 connected in a triangle.

(0) замыкания, предполагаемого в начале линии, а группа аналогичных реле 24-26 - на сопротивление

(l) замыкания, предполагаемого в конце линии.According to the proposed method, each resistance relay is duplicated by relays similar to it, differing only in their characteristics. In Fig. 5, groups of similar relays 19, 20 are shown consisting of each of three resistance relays. A group of similar relays 21-23 reacts to resistance

(0) circuit, assumed at the beginning of the line, and a group of similar relays 24-26 - resistance

(l) the closure proposed at the end of the line.

Groups of executive relays are formed from representatives of similar relay groups. Since figure 5 shows only two groups of similar relays, then in each group of executive relays there can be only two resistance relays. In total, Fig. 5 shows three such groups 27-29, although the total number of executive groups, which can be composed of three-element groups of similar relays, is nine. The outputs of all relays of the same executive group are connected according to the AND 30-32 circuits, and the outputs of all groups are connected according to the OR 33 circuit.

The number of groups of similar relays, as well as the number of executive groups, is not limited. So, in the implementation of the method of FIG. 6, designed to protect against two-phase earth faults, six groups of 34-39 similar relays are provided, of which three groups of actuating relays are assembled, as in FIG. 5. But if in figure 5 they were two-element, then in figure 6 each such group consists of six relays. The output protection signal is formed by six-input circuits AND 40-42 and the terminal circuit OR 43.

Groups of similar relays are functionally connected to the selected transverse branches of the alleged damage; the number of such groups is determined by the number of these branches and is therefore relatively small. The number of relays in the group is not limited by anything and is determined by a compromise between the desire to increase the sensitivity of protection and the need not to complicate its structure too much.

(0), а также и их характеристикам присвоен символ “а”, а всему, что связано с

(l), - символ “b”. Реле 21, 22, 23 и их характеристики обозначаются соответственно как а1, а2, а3, а реле 24, 25, 26 - как b1, b2, b3. Форму и размеры областей срабатывания задают на основании имеющегося опыта или в ходе испытаний защиты на имитационной модели электропередачи. Помимо областей срабатывания на стадии настройки защиты составляют еще и группы исполнительных реле. В примере по фиг.5 возможно девять сочетаний из двух реле, принадлежащих разным трехэлементным группам - 19-20. Сочетания могут быть обозначены кодами:Each of the resistance relays, which is part of a particular group of similar relays, is given a tripping characteristic on its complex plane. For example, for the structure in Fig. 5, where two groups are involved, each of the three relays, two complex planes are considered and on each of them three response areas (Fig. 7). To simplify all resistance-responsive relays

(0), as well as their characteristics, the symbol “a” is assigned, and everything connected with

(l), is the symbol “b”. Relays 21, 22, 23 and their characteristics are designated respectively as a1, a2, a3, and relays 24, 25, 26 - as b1, b2, b3. The shape and size of the response areas are set based on existing experience or during protection tests on a simulated power transmission model. In addition to the triggered areas, at the stage of setting up protection, there are also groups of executive relays. In the example of FIG. 5, nine combinations of two relays belonging to different three-element groups — 19–20 — are possible. Combinations can be indicated by codes:

1) a1-b1, 2) a1-b2, 3) a1-b3, 4) a2-b1, 5) a1-b1, 6) a2-b3, 7) a3-b1, 8) a3-b2, 9) a3-b3.

In the classification of combinations, we will proceed from the conditions under which all relays included in this particular combination operate. Then four types will be revealed. The first is the one whose all relays are triggered by a circuit in the protected zone. The second only works in alternative modes, for example, when faults are outside the zone. The third does not work at all in any modes. Finally, the fourth type reveals traits of both the first and second types, i.e. It works both with faults in the zone and in alternative modes. Suppose the characteristics of the relay shown in Fig. 7 are selected in such a way that only three combinations belong to the first type, namely: 1) a1-b1, 5) a2-b2, 9) a3-b3. The remaining six belong to other types and therefore are not considered further. The groups of executive relays are only from combinations of the first type. In this case, the first executive group 27 is built by the combination of a1-b1, the second 28 - by a2-b2, the third 29 - by a3-b3.

In the example of FIG. 6, where six groups, each of three similar relays, on three complex planes define three response areas. The executive group includes only such combinations of six relays, representing each group of similar relays 34-39, which operate without exception only in the protected zone.

The proposed method allows a single-system implementation of distance protection. The universal structure contains six groups of similar relays for each of the two places of the alleged closure indicated above, but in this case there will be twelve executive relays for each group. A simpler multi-system implementation, consisting of two parts in FIGS. 5 and 6. It is assumed that this type of distance protection has a phase selector that recognizes damaged phases, and the modules in FIGS. 5 and 6 solve only their own fault recognition problem in the protected area. If necessary, the phase selection function can be transferred to the same modules, for which it is enough to take into account the closure of alien species as alternative modes during the training of each individual module.

,

,

, междуфазные

,

,

, и двухфазные на землю

,

,

. Реле сопротивления, входящие в состав каждого из указанных модулей, обладают собственными характеристиками срабатывания, которые учитывают среди прочего еще и реальную несимметрию линии.Thus, the implementation of distance protection under consideration contains a total of ten modules in terms of the number of possible types of faults with different special phases: symmetric three-phase fault К ⁽³⁾ , single-phase faults,

,

,

interphase

,

,

, and biphasic to ground

,

,

. The resistance relays included in each of these modules have their own response characteristics, which take into account, among other things, the real asymmetry of the line.

Remote protection based on the proposed method, operates as follows. In normal mode or in case of faults outside the protected zone, none of the executive groups of the resistance relay, no matter which of the ten marked modules it enters, will work. Of course, part of the relay in the executive group can work in these modes, but all together - never. Consequently, in the listed modes, alternative to controlled, it is impossible to trigger any of the schemes And 30-32, 40-42. False protection work in the modes taken into account during its training is impossible.

все прочие девять видов замыканий в любом месте линии относятся к альтернативным режимам, то и при эксплуатации защиты замыкание

в контролируемой зоне будет иметь следствием срабатывание всех реле одной из исполнительных групп 27, 28 или 29. Допустим, сработали реле 21, 24 группы 27. Тогда через схемы И 30 и ИЛИ 33 сигнал о замыкании в зоне поступит на выход защиты. Если автономный блок фазового селектора в структуре защиты не предусмотрен, то одновременно с сигналом о замыкании в зоне формируется сигнал о виде замыкания, в данном примере

. Все остающиеся девять модулей других замыканий в данном случае не срабатывают. Аналогичным образом дистанционная защита отрабатывает остальные однофазные и междуфазные замыкания. Сложные виды замыканий имеют особенности, учитывающиеся на стадии обучения. Например, для замыкания

однофазные замыкания

и

, равно как и междуфазное

, не обязательно рассматривать как альтернативные режимы, если все они происходят в защищаемой зоне. При таком подходе допускается одновременное срабатывание модуля

и еще скольких-то или даже всех модулей

,

и

. Сигнал срабатывания защиты будет продублирован, что не может вызывать возражений, а о виде замыкания будет свидетельствовать срабатывание старшего по сложности распознаваемого замыкания модуля двухфазного замыкания на землю. По такому же принципу проводят настройку и модуля трехфазного замыкания К⁽³⁾. Для него режимы междуфазных замыканий в защищаемой зоне могут быть исключены из перечня альтернативных режимов.Now suppose that a fault occurred in the controlled area. In order to determine the protection behavior, it is important to find out which of the four combinations of the relay response areas described above refers to this emergency mode, in other words, how did this mode or one close to it manifest itself during the training of protection, and whether the relay executive group was formed for it. It could be that the relays operating in this mode at the training stage formed a combination of the fourth type, i.e. they worked not only in this, but also in some of the alternative modes. As noted above, relay combinations of this kind are ignored, i.e. Do not go into the category of executive groups. An executive group is formed only if the corresponding combination of representatives of different groups of similar relays did not work in any of the alternative modes. If at the stage of training distance protection it was accepted that for

all other nine types of faults in any place of the line belong to alternative modes, then during operation protection

in the controlled zone, all the relays of one of the executive groups 27, 28 or 29 will be triggered. Suppose, relays 21, 24 of group 27 have tripped. Then, through the AND 30 and OR 33 circuits, the signal about the circuit in the zone will go to the protection output. If an autonomous phase selector unit is not provided in the protection structure, then a signal about the type of closure is formed in the zone at the same time as a signal about a fault in the zone, in this example

. All the remaining nine modules of other faults in this case do not work. Similarly, distance protection fulfills the remaining single-phase and interphase faults. Complex types of closures have features that are taken into account at the training stage. For example, to close

single phase short circuits

and

, as well as interphase

, not necessarily considered as alternative modes, if all of them occur in the protected zone. With this approach, simultaneous operation of the module is allowed.

and how many or even all modules

,

and

. The protection operation signal will be duplicated, which can not cause objections, and the type of circuit will be indicated by the operation of the senior in complexity of the recognized circuit fault of the two-phase earth fault module. By the same principle, the three-phase circuit module K ^{(3) is} also tuned. For it, the modes of interphase faults in the protected zone can be excluded from the list of alternative modes.

The proposed method is universal in that it does not impose any restrictions on its implementation. The number of individual resistance relays, the form and position of their characteristics, the number of executive groups are selected as necessary to ensure maximum sensitivity of distance protection and the absolute exclusion of the probability of false operation. Of course, it is possible to vary the locations of the alleged faults, however, experience has shown that the decision to choose two locations - at the beginning and end of the protected zone - is optimal.

Sources of information

1. USSR Copyright Certificate No. 66343, cl. H 02 H 3/28, 1944.

2. Schneersen E.M. Remote protection. M .: Energoatomizdat, 1986, p. 88-89.

3. RF patent No. 2066511, cl. H 02 H 3/40, G 01 R 1/08, 1992.

4. RF patent No. 2149489, cl. H 02 H 3/40, G 01 R 31/08, 1999.

5. Recognition of power transmission damage. Part 1-3, Electricity, 2001, No. 2, 3, 12.

Claims (4)

1. A method for remote protection of a power line, according to which the measured currents and voltages are converted together with a priori information about the line into currents and fault voltages assumed at fixed locations on the line, and the converted values of each prospective fault location are supplied to the corresponding resistance relay, characterized in that, in order to increase the sensitivity of protection, they form groups of similar resistance relays, for which they duplicate each main resistance relay similar to by completing relays and supplying to the additional relays the same values as for a similar main relay, make up from the representatives of groups of similar relays the groups of executive relays, moreover, only one of the similar relays is introduced into the group of executive relays, the output signals of all relays of the same executive groups are combined by the logical operation AND, and the output signals of all groups of executive relays are combined by the logical operation OR, the result of which is used as the output signal of distance protection. 2. The method according to claim 1, characterized in that the location of the alleged damage is selected at the beginning and end of the protected zone. 3. The method according to claim 1, characterized in that the measured currents and voltages are divided into the preceding and emergency components, they are individually converted to the corresponding components of currents and voltages at the alleged locations of the faults, emergency components of the currents are taken as the currents of the proposed faults, summarize the voltage components of the same place of the proposed fault and take the amount as the voltage of the proposed faults. 4. The method according to claims 1-3, characterized in that each place of the proposed circuit is assigned six groups of similar resistance relays, three phase and three phase-to-phase, and make up separate groups of executive resistance relays for each type of circuit, into groups of executive relays protection against a single-phase circuit includes representatives of the corresponding groups of similar phase relays of the beginning and end of the zone, the groups of executive relays of protection against phase-phase circuit include representatives of the corresponding analog groups ary phase-phase relays start and end zone, and a group of executive relay from the two-phase earth faults include both representatives of the respective groups of similar phase relay start and end zone, and representatives of the respective groups of similar phase-phase relays these two places the transmission line.

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