DE572278C - Circuit arrangement for monitoring electrical distribution networks - Google Patents

Description

The invention relates to a circuit arrangement for monitoring electrical Distribution networks with several connected to one common supply current source Feed lines. In systems of this type, it is often necessary in certain operating states switch them off automatically in a feed line. For this purpose, relays dependent on the energy direction are

to applies which one between the concerned Switch off the feed line and the mains switch as soon as energy is received from the Distribution network flows into the feed line, and close this switch again as soon as the correct operating status has been restored in the feed line. Both known arrangements of this type are now available when switching on the Switch does not take into account the phase and size relationship of the supply voltage taken from the mains voltage, so that an interconnection of the network with a feed line could take place without in Both circuits are synchronized and there is a suitable voltage ratio.

The present invention aims to obviate this inconvenience. This is according to the invention achieved in that the current coils of the energy direction relay to the winding of one in the connecting line between the secondary winding of the supply transformer and the network lying current transformers are connected and that the current transformer has auxiliary windings which are arranged such that the current coil of the energy direction relay is traversed by a current after interruption of the connection line, which is dependent on the phase and voltage difference between the feed line and network.

The current transformer expediently has one on the secondary winding of the supply transformer lying voltage winding, which, when the switch is closed, acts in such a way that the amount of energy required is necessary to bring the energy direction relay into the switch-off position, directly changes with the voltage in the feed line.

The invention will now be based on the exemplary embodiments shown in the drawings described. In the various figures, the corresponding parts have been given the same reference numerals so that It is sufficient if the devices shown are described in detail using Fig. 1 while the remaining figures

can only be described as far as they differ from Fig. ι.

In Fig. Ι is a single-phase distribution network with ι denotes, which via several feed lines 3 from one or more supply current sources connected to the busbar 2 is fed. Each feed line 3 contains a transformer 4, with its low-voltage secondary winding is connected to the network through a switch 5, while the primary winding of the transformer is connected through a switch 6 to the Busbar 2 is connected. The transformers 4 and the switches 5 are as usual, placed in the vicinity of the network 1, while the switches 6 in the Central unit containing the feed current source are arranged.

The switches 6 are provided in a known manner with a latch through which they be held in the on position. The switches are switched off by that either by hand or automatically by means of an overcurrent relay 9, which via the current transformer 10 to the associated The supply circuit is switched on, the latch 8 is triggered. The closing devices are not shown because they are superfluous for understanding the present invention.

The switches 5 are designed in a corresponding manner. The closing coil is with 11 and the trigger coil with 12.

To when the primary circuit is interrupted by switch 6 or when it occurs a fault in the feed line 3 or in the transformer 4 to cause the switch 5 to switch off automatically, an energy direction relay is assigned to each switch 5, which is connected to the network 1 lying voltage winding 16 and a current winding 17, which is connected to the secondary winding a current transformer 19 is connected, the primary winding 20 with the switch 5 closed between the secondary winding of the transformer 4 and the network. The energy direction relay 15 are designed so that, if more than a certain small amount of energy flows from the network to the transformer, the relay their usually closed, in the excitation circuit for the closing coil 11 des associated switch 5 lying contacts 21 open and their in the excitation circuit for the opening coil 12 of the switch 5 lying contacts 22 close.

So that the energy direction relay 15 at the appropriate phase and size ratio of the secondary voltage of the transformer 4 and the mains voltage can cause the switch 5 to be switched on again, is the Current transformer 19 is provided with a tertiary winding which is arranged so that when the switch 5 is open by a certain difference between the secondary voltage is excited at the transformer 4 and the mains voltage. As can be seen from the drawing, the winding bridges 24 the switch 5. A suitable current limiting device, for example a high-value resistor 25 connected in series with the transformer winding 24.

'The winding 24 causes that when open Switch 5 via the current coil 17 of the associated energy direction relay 15 Current flows, depending on the phase and size ratio between the secondary voltage at the transformer and the mains voltage changes.

The mode of operation of the arrangement shown in Fig. 1 is as follows: It is assumed that that the switches 5 and 6 are closed in one of the supply circuits and that the switches 5 and 6 are open in the other supply circuit. Under these Under certain circumstances, the voltage coils 16 of both energy direction relays 15 are through the network voltage and the current coil 17 of the relay 15 assigned to the closed switch 5 excited by the current flowing through the closed switch 5 to the network. As a result, the relay 15 keeps its contacts 21 closed and the contacts 22 open. Since the winding 24 and the resistor 25 assigned to the closed switch 5 are short-circuited, almost all of the Current running through the closed switch through the primary winding 20 of the closed switch 5 associated with it Current transformer 19.

The energy direction relay 15 assigned to the open switch 5, however, holds its own Contacts 21 open and its contacts 22 closed, since the circuit is on the Winding 20 of the associated current transformer 19 is interrupted and the winding 24 is excited by the small ^ overcurrent flowing through it to the secondary winding of the unexcited transformer 4.

When the open switch 6 is closed, so that the associated transformer 4 is excited by the supply current and when the secondary voltage of the transformer 4 is in a certain ratio to the mains voltage, for example slightly larger and is approximately in phase with the mains voltage, then the winding 24 induces the the open switch 5 associated current transformer 19 in the secondary winding 18 of the transformer. 19 a voltage of suitable phase in order to

to influence ordered energy direction relays 15 in such a way that that it closes its contacts 21. As a result, the closing coil 11 and the auxiliary contact 30 of the open switch 5 to the secondary winding of the transformer 4 laid. As a result, the switch 5 is closed and the secondary winding of the transformer 4 connected to the network. By interrupting the auxiliary contacts 30 when the switch 5 is closed, the switch-on coil 11 is de-energized, the switch but is by the pawl 13 in the on position held.

When the switch 6 is closed and energy from the feed line 2 to the network is transmitted, stands in the current coil 17 of the energy direction relay 15 through the over the winding 20 of the current transformer 19 generated current in the appropriate Phase relationship to the current in the voltage coil 16 of the relay 15 to a suitable To generate moment such a direction that the contact 21 remains closed. So long So energy is transferred from the busbar to network 1, remains the assigned switch 5 closed.

If a switch 6 is opened or a fault occurs in a feed line 3, so that energy flows backwards via the associated switch 5, causes the reverse current Such a change via the primary winding 20 of the current transformer 19 the phase of the current in the current coil 17 of the associated relay 15 compared to the Current in the voltage coil 16 of the relay 15 that the direction of the exerted by the relay The moment is reversed and the contacts 21 are opened and the contacts 22 are closed will. The opening coil 12 and the auxiliary contacts are connected via the contacts 22 31 of the switch S placed on the secondary winding of the transformer 4, so that the Switch 5 is open and the secondary winding of transformer 4 is disconnected from network 1 will.

After switch 5 has been opened

is, it can be automatically closed again in the manner described above, if

. the secondary voltage of the transformer in a suitable size and phase relationship to the mains voltage.

In some cases it is desirable that the energy direction relay 15 be arranged so that that under normal stress conditions a large amount of energy flowing back is necessary to switch the relay 15 to the off position to bring, and that this amount decreases with decreasing supply voltage. For this purpose is in the embodiment Fig. 2 the transformer 19 with a fourth winding 35 and the switch 5 with the Auxiliary contacts 36 provided, the winding 35 is arranged so that they, if they is connected to the network, depending on the secondary voltage of the associated Transformer is excited. To limit the current through winding 35 is the high resistance 3 placed in series with her.

The windings 20 and 35 are arranged so that, if under normal voltage conditions In the supply circuit, a certain amount of energy flows to the supply circuit through the windings 20 and 35 in the secondary winding 18 resulting voltage generated a current flow causes the current coil 17 of the associated energy direction relay, which together with the current in the voltage coil 16 to open the relay contacts 21 and to Closing the contacts22 produces sufficient torque, and that further at an approximately same amount of returned energy, but below the normal value of the supply voltage, which is in the secondary winding 18, the resulting voltage induced a current to flow across the current coil 17 of the associated energy direction relay 15 caused, the resulting, by the Coils 16 and 17 generated torque not in direct proportion to the change in Supply voltage decreases.

This is achieved, for example, by dimensioning the winding 18 and 35 of the Transformer 19 achieves that the phase of as a result of the energization of the winding 35 alone The current flowing through the current coil 17 of the relay 15 is such that the current from this Current and the current in the winding 16 of the relay 15 generated resulting torque acts in a direction which seeks to keep the relay contacts 21 closed.

Characterized in that the winding 35 is induced in the associated secondary winding ■ Voltage changes, the amount of reverse flow required to operate the relay 15 is Energy directly dependent on the supply voltage.

In the embodiment of Fig. 3 the same purpose is used as in Fig. 2 with the winding 35 is achieved, achieved in that the auxiliary contacts 36 are arranged on the switch 5 in such a way are that with the switch 5 closed, the winding 24 of the transformer 19 and a suitable current limiting device, such as resistor 38, in series are connected via the secondary winding of the associated transformer 4. At this Arrangement therefore controls the winding 24 of the relay 15 both when opening and when Close the switch 5.

The arrangement according to Fig. 4 differs

differs from that in Fig. ι in that em double-pole switch is provided. Otherwise, the control devices are arranged in the same way. The energy direction relay 15 is provided with two current coils 17 ° and 17 '', which are connected to the windings i8 ^a and 18 * of the two current transformers 19 "and i9 ⁶ , the primary windings 20 ^a and 20 * in series with the different poles of the The tertiary windings 24 ° and 24 * bridge the associated poles of the switch · $, and they are in series with the resistors 2S ^a and 25 *.

In the embodiment of Fig. 5, each Stromtränsformator 19 is with two differentials arranged windings 25 and 26, which are connected so that they are at open switch 5 by the securidärao voltage of the associated transformer 4 or the mains voltage 1 are excited. When the The switch is therefore the current coil 17 of the associated energy direction relay 15 a voltage is applied, which depends on the phase and size relationship of the Secondary voltage of the transformer 4 and the line voltage is dependent. To limit the current through windings 25 and 26, the high-ohmic resistors 27 and 28 are connected in series with them. When the windings 25 and 26 are pressed Voltages are equal and in phase is made possible by these windings in the transformer no field generated. When switch 5 is closed, there is a differential between the two switched windings only the winding 25 is energized. Therefore, in this case, the current coil 17 of the associated energy direction relay 15, a voltage is applied, which equal to the resultant of that in the current transformer winding through the windings 20 and 25 induced voltage. The windings 20 and 25 are arranged so that they both, if energy flows from the associated feed line to the network, in Circuit of the winding 17 cause a current which causes the relay 15 keeps its contacts 21 closed. However, if the direction of energy is reversed, act the windings 20 and 25 against each other, and when the electromagnetic Force of the winding 20 predominates, the relay 15 opens its contacts 21 and closes its Contacts 22. The amount of reverse current required to close contacts 22 depends on the voltage impressed on the winding 25. As a result, the changes to operate the relay 15 required amount of return energy approximately directly with the secondary voltage of the assigned Transformer 4.

Claims (8)

Claims. i. Circuit arrangement for over- ⁶ S monitoring electrical distribution networks with multiple feed points in which each feed line trains classifies the removal and reconnection of a feed line switch controlling energy directional relay, characterized in that the current coil (17) of the energy directional relay (15) whose voltage coil (16) on the network (1) is connected to the winding (18) of a current transformer (19) located in the connecting line between the secondary winding of the supply transformer (4) and the network (1) and that the current transformer has auxiliary windings (24) which are in such a way are arranged that the current coil (17) of the energy direction relay is traversed by the switch (5) after the connection line is interrupted by a current which is dependent on the phase and voltage difference between feed line (3) and network (1). 2. Circuit arrangement according to claim i, characterized in that the Current transformer (19) an auxiliary winding (24) bridging the switch (5) owns. 3. Circuit arrangement according to claim 2, characterized in that the Auxiliary winding (24) is in series with a high resistance (25). 4. Circuit arrangement according to claim i, characterized in that the Current transformer (19) one to the secondary winding of the supply transformer (4) has lying voltage winding (35), which when the switch is closed causes the amount of energy required to control the energy direction relay (15) to the switch-off position, directly with the voltage in the feed line (3) changes. 5. Circuit arrangement according to claim 4, - characterized in that the circuit · of the voltage coil (35, Fig. 2) runs through auxiliary contacts (36) of the switch (5) which are closed when the switch (5) is switched on. 6. Circuit arrangement according to claim ι to 4, characterized in that that the voltage coil (25, Fig. 5) in the off position of the switch (5) is connected differentially with a voltage coil (26) excited by the mains. 7. Circuit arrangement according to claim 6, characterized in that dei Circuit for the mains voltage coil (26) via auxiliary contacts (29) closed when switch (5) is switched off 'of the switch (5) (Fig. 5). 8. Circuit arrangement according to claim ι to 7 for systems with double-pole switches in the feed lines, characterized in that a current transformer (19 ° or 19 *) is provided for each pole, each of which with a special current coil (17 °, 17 ⁵ ) of a single energy direction relay (15) is connected (Fig. 4). For this purpose 2 sheets of drawings