DE608637C - Device for protecting parallel lines - Google Patents

Description

GERMAN EMPIRE

ISSUED ON
JANUARY 28, 1935

REICH PATENT OFFICE

PATENT LETTERING

JVl 608637 CLASS 21c GROUP 6850

21C S 368.

Patented in the German Empire on August 19, 1930

The known circuits for protecting parallel lines are based on a comparison the current strength of the individual parallel conductors. If there are more than two parallel conductors, the Protection only achieved when the parallel conductors have the same resistance, so for example, have the same length and the same cross-sections. In addition, the

to known polygon protection devices the disadvantage that the selection of the sick Leiters only succeeds as long as there are more than two managers in the company. The two last conductor on the other hand are switched off at the same time if on one of these a mistake arises for both of them.

The invention, which not only for plants can be used with double lines, but with any number of parallel lines, eliminates in addition to those already mentioned Defects also the disadvantage of known arrangements that the selectivity by different high speed of the relays dependent on the energy direction is disturbed. The one to determine the energy directions provided relays are switched on simultaneously according to the invention in the event of a fault by a common auxiliary relay, and because as a result of the unilateral disconnection of the diseased line, the direction of energy changes in some lines, the arrangement can be made according to the further invention so that the auxiliary relay the Energy direction relay switches on several times at the same time within a certain time. In between, the relays are given the opportunity to set themselves differently for the In the event that the energy direction of the relevant line to which the relay belongs is changed Has. When using energy direction relays with an auxiliary worker for contact closure, i. H. for example such energy direction relay, the contact member of which adjusts itself freely and then for example by a drop bracket on one of two contact pieces located under the contact track is depressed, a timer is used according to the further invention, which switches the auxiliary power of the converter relay on and off again several times.

Further details of the invention are described with reference to the figure. In this two control centers I and II are represented by the symbol of a generator each. From station I three parallel lines a, b, c are fed via a busbar 2. The ends of these lines, which are located in station I, are equipped with switches a _v O ₁ UmIc ₁ / which can be opened by trip _{coils a 10} , & ₁₀ and C ₁₀ .

In station II, lines a, b, c are also connected by a busbar.

*) The patent seeker stated as the inventor:

Dr.-Ing. Max Katsschner in Mannheim.

608607

connected to the other and also provided with switches a ₂ , b ₂ , C ₂ , which can be opened automatically by the protective device in the event of a line fault. The arrangements in stations I and II are completely identical to one another as long as the lines from station I are routed to station II. Therefore, only the arrangement of ίο Station I is described in more detail below.

An energy direction relay R _a , R _b , R _{c is} provided on each line a, b, c in the station. The energy direction relay is, for example, of such a type that a ^{hinged armature magnet α} ιι>& 1U ^c n must be excited for the contact closure. A contact arm, for example, is then connected to the movable system of the directional relay and has an insulating plate at its upper end. Each energy direction relay has two contacts, and the insulating plate of the energy direction relay is positioned over the left contact when the relay ^{armature deflects to the left and over the right contact when the directional relay deflects to the right, so that when the hinged armature magnet} _{O 11 has} an armature a ₁₂ below presses, a conductive connection between the hinged armature O ₁₂ and that relay contact which is covered by the insulating plate is prevented by the insulating plate. When the energy direction relay deflects to the left, for example, a conductive connection is only established between the hinged armature contact a ₁₂ and the right contact of the direction relay. The direction relay R _a , which is assigned to the line α , includes the hinged armature magnet O ₁₁ and the hinged armature Cf ₁₂ . In a corresponding manner, a hinged armature magnet b _n and a hinged armature b ₁₂ belong to the direction relay R _{b of} the line b . In the case of the direction relay R _{c of} the third line c, the parts C ₁₁ and C ₁₂ are correspondingly present. The stations also contain start relays for each line. In the illustration, a trigger relay n _a , ftb, n _{c is shown} , as well as two _{timing relays Z 1} and Z ₂ , of which only the timing relay Z ₁ is necessary for the implementation of the protective circuit, which is the subject of the invention. The timing relay Z ₂ is only used for overcurrent protection overlaid for safety. In addition, an auxiliary relay h _a , h _b , h _c belongs to each line, the mode of operation of which will now be explained in connection with the processes that take place when an error occurs.

It is assumed that an error occurs on line b , and that the error occurred closer to station I than to station II, so that it can be assumed that before one of the line switches on line b is open, the fault current enters from both sides via the section b , while the lines α and c carry overcurrent in the direction from station II to station I.

In station I, the start relay if all three lines overcurrent result, the pickup relay Ha, T., "and address n ^c. The same will be the case in the station II. N ie _a closes its contact and is characterized on the one hand the connection of the folding magnet O ₁₁ to the negative terminal of the local battery forth. On the other hand, the auxiliary relay h _a energized, which closes its contact immediately. About the contact of the auxiliary relay h _a and a closed-drawn closed contact of the time relay Z ₁ is this time relay energized Z _1. the time relay Z ₁ begins to run and after a short time initially closes a normally open contact. This completes the circuit for exciting the folding magnet a _{n of} the direction relay R _a . The current runs from the positive pole via the closed contact of the auxiliary relay h _a , the normally closed contact of the timing relay Z ₁ , the now closed normally open contact of the timing relay Z ₁ , the winding of the magnet a _n and the closed en Contact of the excitation relay n _a to the negative pole of the local battery. As soon as the magnet C _{11 is} excited, the hinged armature a ₁₂ is struck down and, since it was assumed that the energy in the conductor α flows from the station II in the direction of the station I, the direction relay R _a beats to the right, so that the hinged armature a ₁₂ comes into conductive contact with the left contact of the direction relay R _a. This brings the hinged armature C ₁₂ into conductive connection with the positive pole of the local battery.

The same processes as with the line α take place in the line c, if here too overcurrent occurs in the direction of station II. The effects of the excitation relays of the various lines on the timing relay Z ₁ run in parallel. In the case of the direction relay R _c , the insulating plate is placed over the right contact so that the hinged armature C ₁₂ comes into contact with the left contact of the direction relay, so just like the hinged armature a _{12 is connected} to the positive pole of the local battery. In the relay device of line b , relays n _b and h _{b also respond} . Here, too, the excitation circuit for the _{hinged armature magnet is} prepared via the contact of the excitation relay n _b , so that the hinged armature magnet is excited as soon as the 'time

_{relay Z 1} closes its normally open contact. The direction relay R _b is knocked out in this .Relaiseinrichtung in contrast to the direction relay of the line α and c to the left, because the energy from the station I flows into the line b . So there is a conductive connection between the hinged armature b ₁₂ and the right contact of the direction relay, and because the armature b ₁₂ , which is conductively connected to the armatures a ₁₂ and C ₁₂ , due to the effectiveness of the relay R _a and parallel to it As a result of the effectiveness of the relay R _{c is} connected to the positive terminal of the local battery, a circuit is now established via the armature b ₁₂ and the right contact of the direction relay R _b via the trip coil O _{10 of} the switch b _t , whereby the switch b _{1 is} opened will. As a result, the faulty route is cut off on one side. At this moment, the energy on lines α and c will be reversed, since it is no longer possible for station II to feed the fault on line b with current via lines ο and c and via busbar 2. After the switch b _{t has been opened} , station I will send power to the busbar of station II via lines ο and c and from there via switch b ₂ to the fault location. The direction of energy on lines α and c is thus reversed.

Before the circuit breaker ^ ₁ had fallen, the three conductors α, b, c at station II had the same current direction everywhere. As a result, the switch b _{2 is} not triggered. One only needs to think of the processes in station I and assume that all the energy direction relays show energy that is dissipating, ie that all the energy direction relays switch off to the left. As soon as the hinged armature magnets a _n , O ₁₁ and C _{11 are switched on} by the timing relay Z ₁ , the hinged armature α ₁₂ , b ₁₂ and c _{ia come} into conductive contact with the right contact of their direction relay. However, since at least one directional relay has a conductive connection between the hinged armature and the left relay contact, so that the hinged armature can be connected to the positive power source of the local battery, all the hinged armatures are de-energized when all the directional relays deflect to the left. As a result, the trip relays a ₁₀ , b ₁₀ and C ₁₀ cannot be energized.

The conditions just considered were initially present in the station as long as the overcurrent in all three conductors was directed away from the station. Now, after the switch b _t has been opened, the energy in the line b is directed away from the busbar, and in the lines α and c it is directed towards the busbar. This results in exactly the same conditions that prevailed before the triggering of switch b _± at station I and which led to the triggering of switch O ₁ alone. In a corresponding manner, only switch b ₂ will now fall.

Now the case would be conceivable that, after the switch O _{1 is} open, the current intensity in the lines α and c decreases so far that the excitation relays of these lines drop out, ie only the excitation relay of line b in station II responds . The current in conductor b is directed away from the station. The directional relays R ₁₁ and R _b can then not be questioned because, as has already been said, one connection of the hinged armature magnets a _n , b _u and C _{11 is} always led via the contact of the associated trigger relay. So there is only the excitation relay n _b, the auxiliary relay h _b, the timing relay Z ₁ and of the hinged armature of the solenoid directional relay R _b at. If overcurrent does not occur in any other line, the line switch b _{2 is} triggered by the already mentioned second time relay Z ₂ and the direction relay R ₂ by connecting the hinged armature b _{12 of} the direction relay to the positive pole of the local battery via the contact of the time relay Z ₂ will.

The timing relay Z _{1 also} has a special feature in order to ensure that the direction relays can be reset after the time required for the first shutdowns has elapsed. For example, as has already been discussed, the direction of energy in station II is reversed in the healthy lines when switch b ₁ falls. So that the switch b _{2 is} now switched off properly, the directional relays R _a , R _b and R _c in station II must be able to reset themselves. For this purpose, the excitation _{circuit for the timing relay Z 1 is} routed via the normally closed contact of the timing relay. This normally closed contact is opened after the normally open contact has closed. The interruption of the no closed circuit has the consequence that the time relay drops out again and the normally open contact opens again. This interrupts the circuit for the hinged armature magnets because this circuit is routed via the normally open contact of the timing relay Z ₁ . Due to the de-energization of the time relay, its normally closed contact is now closed again and it begins to run again. The timing relay has the peculiarity that, as long as a start relay is excited, it pumps and thereby the hinged armature

magnet temporarily switches on and off again.

It is not absolutely necessary that the direction relays used have a hinged armature and hinged armature magnet. Rather, those can also be chosen which make direct contact by moving the relay armature to the right or to the left against a mating contact, where then

ίο there is still an interruption point in series with the relay armature, which is closed by the time relay Z ₁ .

It is an advantage of the invention that for the implementation of the protection of the parallel Conductors of any length and any cross-section are no new types of relay designs must be used. Only current direction relays or energy direction relays are used to eliminate the diseased line, Timing relays and DC auxiliary relays as well as overcurrent or resistance relays for the suggestion needed.

Claims (4)

Patent claims: i. Device for protecting parallel lines, in particular cables, by means of a relay device which responds only to a difference in the energy directions in the individual parallel lines, characterized in that the relays (R _a , R _b , R _c ) provided for determining the energy directions in the event of a fault can be switched on simultaneously by a common auxiliary relay (Z _1). 2. Device according to claim 1, characterized by a timer (break contact of the relay Z ₁ ) for all switch tripping of the parallel lines coming together in the station, which prepares the triggering of the switches (a _v Z) ₁ , C _{1) several times in certain time stages.} 3. Device according to claim 1 or 1 and 2, characterized by a further time switch (Z ₂ ) which, after a longer delay time has elapsed, triggers those switches in which the outgoing current direction prevails when the excitation relay (n _a , n _b , n _c ) have not responded in the healthy lines due to insufficient fault current. 4. Device according to claim 1 or the following, in which the individual lines are each equipped with a current direction relay, characterized in that the StroHirichtungrelais (R _a , Rj ,, R _c ) only those lines (α, b, c) come into action whose associated start relays (n _a , lib, ti _c ) have responded. 1 sheet of drawings