DE520924C - Selective protection for multi-phase networks - Google Patents

Description

GERMAN EMPIRE

ISSUED ON
APRIL 20, 1931

REICH PATENT OFFICE

PATENT LETTERING

M 520 CLASS 21c GROUP

Selective protection for multi-phase networks Patented in the German Empire on February 9, 1924

If there is a two-pole short circuit in a three-phase network that feeds many electric motors occurs, these motors consume more current in the conductor that is not affected by the short circuit than in the normal three-phase Operation. The consequence of this is that, without causing difficulties for the individual motor, the increased consumption of electricity grows into an overcurrent which triggers switches that have nothing to do with the short circuit. It happens that switches on several Trigger points that are far from the short circuit. It doesn't just talk the overcurrent relays wrongly because they are epidemic-like across the entire network received spreading short-circuit current, but it can also happen that the energy direction relay lash out on the net in the wrong sense. It can even happen that those energy direction relays, through which the short-circuit current flows and through which the diseased section should switch off, deflect incorrectly and that with the trigger circuit of the switch not conclude. Such inconveniences are intended to be remedied by the invention.

According to the invention occurs in a selective protection device for multi-phase networks in which relays with current and voltage coils are provided in the same number as phase lines, depending on which phase lines are affected by the error, the relay assigned to them, which is affected by the difference in the currents in the sick Phase lines is energized, in action. This is the most reliable way of ensuring that only the currents and voltage conditions directly caused by the fault cause the switches to trip. Protection circuits are known in which relays with current and voltage coils are also provided, which only come into operation when an error occurs. However, these relays are not influenced by the difference in the currents in the diseased conductors. Therefore, in contrast to arrangements according to the invention, these devices only work reliably in the event of a certain type of malfunction. g ₀

Some exemplary embodiments are shown in the drawing. The phase lines a, b, c go out from the busbars R, S, T and are switched off by the switch d when the coils of the tripping circuit break the latch /. For the branched line, b, c three energy direction relays R ₁ , R ₂ , R _& are arranged, each of which is provided with two current coils lying in different phases to one

'■') The patent seeker stated as the inventor:

Richard Bauch in Berlin-Charlottenburg.

Form current difference to_. This ensures that the relay to currents that the Size and direction are the same, do not address.

In Fig. Ι the voltage coils S ₁ , S ₂ , S3 of the relay are connected between an artificial zero point η and a phase. The current coils ie and 4 of the direction relay ^ ₁ , for example, are in phases α and &; the ίο voltage coil S ₁ lies between the zero point η and the phase c. The relay coils can of course also be connected via current or voltage converters. According to the invention, the contacts A ₁ are now connected in the circuit of one of the relay coils, e.g. the voltage coil S ₁ , and are kept open by the contactor g connected in phases and as long as there is voltage between these phases. The device works in the following way: When the line is in normal operating condition, the energy direction relays do not respond because their voltage coils are switched off. If, however, a short circuit occurs between phases β and b , this has the consequence that the voltage between these lines collapses. The coil g "therefore drops its core and _{short-circuits the contacts A 1} , whereby the voltage _{coil S 1 is switched} between the zero point« and the phase c . The directional relay R ₁ now trips and closes the circuit of the trip coil e, whereby the Switch d is opened.

If the overload occurs in other phases, do the corresponding energy direction relays R ₂ or /? ₃ and trigger the switch d .

Instead of connecting the voltage coils of the energy direction relay between an artificial zero point and each phase, they can also be connected directly to the triangular voltage, as shown in Fig. 2. The voltage coil S ₁ is connected, for example, between the phases b and C _1, the voltage coil S ₂ between the phases c and and the voltage _{coil S 3} between the phases and. Otherwise, the ■ operation of the device is the same as that of Fig. 1.

go To form the current difference, the direction relays are shown in Figs. ι and 2, each with two Provided current coils, which are directed against each other. But you can use the relays also equip only with a current coil and a voltage coil. A current difference can then be formed by means of two current transformers, their primary coils in two Phases lie and their secondary coils in figure eight to the current coil of the energy direction relay are connected.

Fig. 3 shows an arrangement in which the voltage coils of the energy direction relays are switched on by overcurrent relays that are switched on in the individual phases. The energy direction relays R ₁ , R ₂ , R _s are, as in the arrangement according to Fig. R, provided with two counter-connected current coils and a voltage coil. The voltage coils S ₁ , S ₂ , S ₃ are connected between an artificial zero point ti and one phase each. The contacts A ₁ , A ₂ , A ₃ in the circuits of the voltage coils are _{flowed by coils A 1} , A ₂ , A ₃ , which are in the circuits of overcurrent relays m _s , tn _v tn ₂ . If an overload occurs in one of the phases a, b, c , the overcurrent relay of the relevant phase responds and closes the circuit of the associated voltage coil of the energy direction relay. This responds and closes the circuit of the trip coil e _} through which the switch el is switched off.

Fig. 4 shows a device in which the voltage _{coils S 1} , S ₂ , S _{3 of} the energy direction relay are permanently connected between two phases, while the current coils are short-circuited in the normal state of the phases. The coils i _a and / j are _{short-circuited by the contacts A 11} and A ₁₂ when the coil., G · is under voltage. If the voltage collapses, coil g drops its core, the current coils of the energy _{direction relay receive current, and relay ^ 1} trips and disconnects the line.

One can switch on the current coils, as described, from the breakdown Make it dependent on the voltage, but you can also make it dependent on overcurrent relays which, similar to Fig. 3, are switched into the three phases.

Claims (3)

Patent claims: 1. Selective protection for multi-phase networks, in the case of the relay with current and voltage coils are provided in the same number as phase lines, characterized in that, that, depending on which phase lines are concerned by the error that assigned to these phases is based on the difference between the phase lines flowing in the phase lines affected by the fault Currents responding relay comes into action. 2. Selective protection according to claim 1, characterized in that by the collapse the voltage between two phases, the relay provided for these two phases is activated. 3. Selective protection according to claim 1, characterized in that by over-