DE1198446B - Earth fault protection circuit for a non-meshed radiation network - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. α .:

HOIh

H02h

German class: 21c-68/70

Number:
File number:
Registration date:
Display day:

C24675VIIIb / 21c
July 21, 1961
August 12, 1965

The invention relates to an earth-fault protection circuit for a non-nibbled radiation network with impedance relays that carry out a comparison with a reference impedance and as a function address from the phase position of the compared impedances.

It has long been known to use zero currents and zero voltages for the purpose of earth fault protection to use. In all known arrangements of this type, however, these variables act exclusively on zero-current relay or on zero-power relay.

In the case of non-networked radiation networks, the use of zero-current relays does not offer a useful one Result. For example, it can be a resistive earth fault in a branch it can happen that the zero current at the connection point of the faulty branch is less than the zero current that would be generated at the same point by a smooth earth fault lying outside the branch. If the zero-current relay is set so that it only responds to the larger of these two current values, it would not cut off the faulty branch in the first case and the healthy branch in the second Cut off branch.

The use of wattmetric relays, on the other hand, enables the sign of the zero-sequence impedance to be differentiated and thus the direction of the earth fault. The distinction of the sign is based on the fact that the wattmetric relay connected to the connection point of a faulty branch measures the power that is delivered from the fault location to the zero impedance of the network in front, while the wattmetric relay, which is connected to the connection points of the remaining healthy branches measure the power delivered by the fault in the zero-sequence impedance of the respective branch that is behind the location of the relay. However, other difficulties arise with the use of wattmetric relays. In fact, if the zero-sequence impedance of the network is small (for example, if the lines of a very extensive network have a large capacitance relative to the ground), the fault current that passes through the relay connected to the connection point of the faulty branch produces a very small one Zero voltage drop. If this zero voltage drop is of the same order of magnitude as the residual fault voltage of the arrangement which generates the zero voltage feeding the relay, the zero power can no longer be determined with the accuracy, earth-fault protection circuit for a not
nibbled radiation network

Applicant:

Compagnie des Compteurs, Paris

Representative:

Dipl.-Ing. E. Prince

and Dr. rer. nat. G. Hauser, patent attorneys,
Munich-Pasing, Ernsbergerstr. 19th

Named as inventor:

Michel Souillard, Sceaux, Seine (France)

Claimed priority:
France of August 5, 1960 (835 077)

which is necessary to ensure the correct operation of the earth fault protection circuit.

On the other hand, there is known a distance relay using an impedance relay, the one Carries out comparison with a reference impedance and depending on the phase position of the compared Impedances responds. In this known arrangement, the measured impedance is determined by a phase voltage and determines a phase current. So it is a real distance relay that compares the reference impedance with the line impedance, which is the distance between the measuring point and is proportional to the point of failure. This distance relay is used to measure the distance of a Line short-circuit from the protection point and is used when successive line sections of a network are to be protected. This is done at each end of each line section such a distance relay is arranged, which responds when the distance of the line short circuit is smaller than the length of the monitored line section represented by the reference impedance and the direction of the line short circuit corresponds to the line section being monitored. ._

Such distance relays would, however, be unsuitable for earth fault protection of such line sections, if the impedance relay instead of the phase current and the phase voltage with the neutral current and the zero voltage would be fed. It would be then

509 630/353

Although still direction-dependent, the trigger circuit of a (not shown) depends on the distance, so that it will also respond to a switch that disconnects the branch from the network,
would, if the earth fault in the corresponding at 24, 25, 26 voltage converters are shown,

Direction on one of the following line whose primary windings with the connection points sections would be. Such a use of these be 5 between the heads of the outgoing branch and Known distance relay was therefore never considered to be connected to the trunk lines 21, 22, 23 and drawn. their secondary windings so interconnected

The object of the invention, on the other hand, is that in the event of a ground fault, they provide a zero-span creation of a ground fault protection circuit for a voltage V _h between terminals D and E , non-meshed radiation network, which is independent of the terminals D and E are connected to a circuit Removal of the fault with certainty the bound that triggers a capacitor 19 with a capacitance disconnection of the faulty branch and rate C, which represents the reference impedance, and which prevents the disconnection of healthy branches. Contains winding 15 of the transformer T _1. Of the

Using impedance relays, which is a value of the reference impedance by the value of the Carry out a comparison with a reference impedance 15 Zero impedance of the branch to be protected is and depending on the phase position of the out of tune; this reference impedance can therefore depending on the respond to the same impedances, this type of zero impedance will be a circuit that would be solved according to the invention in that a capacitance, a self-induction coil, a each connection point of a branch of the network a resistor or a combination of these three Impedance relay is connected such that it contains 20 elements.

the zero voltage existing at the connection point In the absence of any earth fault in both the

and with the flow through the associated branch 11, 12, 13 as well as at every other point the zero current is fed, and that the reference of the network are the zero current and the zero impedance is dimensioned so that the impedance relay voltage zero. If, on the other hand, a ground fault occurs in the above-mentioned only to a certain sign of the network determined by the branch or at any other point of the zero voltage and zero current, the zero impedance measured between the relays responds. a zero voltage TJ _{h at} terminals D and E ,

The invention is based on the knowledge that and the secondary winding of the current transformer 14 does not emit a zero current Ί ,, when a ground fault occurs in one, which is an impedance relay through the series connected to the network of rays, the 3 ° the terminals A and B of the secondary winding of the windings 17 and 15 connected to the transformer with the zero voltage and zero current supplied to the transformer, regardless of the distance of the fault, only the transformers T ₂ and T ₁ flows. Because winding 17 of transformer T ₂ measures two clearly different values, the zero impedance current 7 flows in a healthy branch, while a current I _{2 flows} through winding 15 of the transducer branch and in the faulty branch, transformer T ₁ = I ₁ -I ₁₁ flows, where T _{1 is the} zero-sequence impedance of the rest of the network with the opposite current, the sign emphasized by the voltage ~ ü _h . A very clear _fen is thus obtained. _{d Di current fa the value} J,

and clear contact. ⁶ z _c

Embodiments of the invention are shown in FIG. 1 where Z _{0 is} the value of the drawing formed by the capacitor 19. Therein shows 40th reference impedance is,

Fig. 1 is a circuit diagram of a first embodiment, the zero impedance Z _n , seen from the location of

form of the invention and protective circuit, has the value Jl .

F1 g. 2 part of the arrangement of F1 g. I ge ° i _h
measured a second embodiment. The current I ₂ can thus be expressed by the following leg Fig. 1 are drawn with 11, 12, 13, the three lines 45:
of a branch of a non-meshed three-phase ~ z _h - Z ₀
Called jet network. One end of this line - £> - - γ, - ~ '^ * · (*)
is to the trunk lines 21, 22, 23 of the °

Radial network connected, of which further it can be seen that, depending on the value

branches (not shown). At 14 is a 50 of Z _h , the current 7, may or may not be zero

Current transformers with a ring-shaped magnetic circuit also have a certain value and around a

posed. A and B are the output terminals of the specific angle leading or lagging _{towards 7 Λ}

Secondary winding of this converter, which can ring around the. In the first case, the off by the modulator M

shaped magnetic circuit is wound. _{The current Z 3} outputted to this has the value zero. In the second case

output terminals are in series the primary windings 15 55 depend on the amplitude and polarity of the current

and 17 of two transformers T ₁ and T ₂ due to Z ₃ of the phase shift between 7 ₂

completed, the secondary windings 16 and 18 tra- and I _n , where the current I _{3 has} the value zero.

gen. A ring modulator M contains a known rate if there is a phase shift _{between 7 2} and 7 _ft.

Way four rectifiers 27,28,29,30. The secondary movement of 90 ° exists.

windings 16 and 18 of the transformers T ₁ and T ₁ , 60 If the ground fault on the branch 11, 12, 13 are in a likewise known manner with the four corner points, the impedance Z ₁ , equal to the zero impedance points of the modulator M is connected . The secondary of the entire network, ie the one resulting from the parallel windings, also contain a center tap. circuit of the zero impedances of the other branches These center taps are connected to the winding 20 resulting impedance, with the opposite sign, of a polarized relay R , which contains a 65 This from the connection point of the faulty branch contact 20 ', which closes when there is zero impedance seen from that is, regardless of the winding 20, a current I _{3 of} suitable polarity and the resistance of the earth fault and its size flows. Closing the contact 20 'controls the position on the branch concerned.

If, on the other hand, the earth fault is outside the branch 11, 12, 13, the impedance Ζ _{Λ is} equal to the zero impedance of the branch.

It follows from this: As soon as an earth fault occurs in a branch of a non-networked network, take the zero impedances seen from the connection points of the branches concerned are one or the other of two clearly different values, depending on whether the earth fault is on the branch in question or on another branch.

The reference impedance Z _c is chosen so that in the event of a ground fault on the branch to be protected, the current I ₃ is directed so that the contact 20 'is closed, while in the other case the current I _{3 has} the opposite polarity so that the contact 20 'remains open.

In particular, for a very small value of the zero sequence impedance Z _{n of} the network, equation (1) takes the form 7 ₂ = -7 _ή ; under these conditions, the current I ₃ causes the contact 20 'to close.

In the case of the in FIG. The arrangement shown in FIG. 2 has the same reference symbols as in FIG. 1. The terminals D and E are connected to the primary winding 41 of a transformer T , which carries two identical secondary windings 42 and 43. The secondary winding 42 is connected to a pair of corner points of a rectifier bridge circuit 46 via the reference impedance represented by the capacitor 44 , while the secondary winding 43 is connected to a pair of corner points of a second rectifier bridge circuit 47 via a capacitor 45 with the same capacitance as the capacitor 44 connected. Furthermore, the terminals A, B of the secondary winding of the current transformer 14 (FIG. 1) are connected to this same pair of corner points of the second rectifier bridge circuit 47. The winding 20 of the relay R is connected to the other pairs of corner points of the two bridge circuits, one corner point of each pair being connected to the corner point of the other pair.

As shown in Fig. 2, the rectification senses of the circuits 46 and 47 are opposite to each other. In the event of an earth fault, a zero voltage ~ ü _{h appears} between the terminals /) and E, and a zero current 7 _ή , which is supplied by the secondary winding of the current transformer, flows in the rectifier bridge circuit 47. In the circles.

42-44 and 43-45 a current flows I ₁ = -Ei- , where

Z _{c is} the value of the reference impedance represented by capacitors 44 and 45 , respectively. It can be seen that a current I ₁ flows in the rectifier bridge circuit, while a current 7 ₂ = 7 ₁ -7 _ft flows in the rectifier bridge circuit 47, ίο The current 7 ₂ can be expressed by the following relationship:

⁷ 2 = ^^ - V (2)

The winding 20 of the polarized relay R is connected in such a way that the contact 20 'is closed when the amount of the current 7 ₂ flowing in the bridge circuit 47 is greater than the amount of the current I ₁ flowing in the bridge circuit 46.

The operation of this protective circuit is identical to the operation of the, depending on the location of the earth fault in Fig. 1 protective circuit shown.

Claims (1)

Claim: Earth fault protection circuit for a non-meshed radial network with impedance relays, the carry out a comparison with a reference impedance and depending on the phase position respond to the compared impedances, characterized in that at each Connection point of a branch of the network an impedance relay is connected in such a way that it with the zero voltage existing at the connection point and with the associated Branch flowing zero current is fed, and that the reference impedance is such that the impedance relay only to a certain sign of the zero voltage and the Zero-current-specific, zero-sequence impedance measured by the relay responds. Considered publications: German patents No. 670 488, 950 737,
326; German interpretative document No. 1009 274. 1 sheet of drawings 509 630/353 8.65 © Bundesdruckerei Berlin