EP1388191A1

EP1388191A1 - Bypass circuit for the overcurrent trip of a low-voltage power circuit breaker

Info

Publication number: EP1388191A1
Application number: EP02726078A
Authority: EP
Inventors: Henry Franke; Manfred Schiller
Original assignee: Siemens AG
Current assignee: Siemens AG
Priority date: 2001-05-14
Filing date: 2002-04-05
Publication date: 2004-02-11
Also published as: WO2002093709A1; JP2004531999A; US20040145844A1; DE10125051A1

Abstract

According to the invention, a bypass circuit (4) trips a power circuit breaker, independently of an existing electronic overcurrent trip (2), as instantaneously as possible when a short-circuit occurs. To achieve this, the bypass circuit (4) is supplied by its own current sensor (3) that is configured as a current transformer in order to charge a capacitor (C), until a threshold value circuit (5) responds. The charge of the capacitor (C) is then fed to a separate tripping magnet (F2) or to a combined tripping magnet (F3) comprising separate coils for the two tripping paths.

Description

description

Bypass circuit for the overcurrent release of a low-voltage circuit breaker

The invention relates to a bypass circuit for the electronic overcurrent release of a current-limiting low-voltage circuit breaker with separate current sensors for the electronic overcurrent release and for the bypass circuit and with a release magnet for releasing an energy store of the circuit breaker.

A bypass circuit of the type mentioned above has become known from EP 0 244 284 B1 (= US 4,733,321). A major reason for using bypass circuits is the required evaluation time of the current signal by an electronic overcurrent release, especially if it has previously been in an inactive idle state. An inactive idle state can exist after the circuit breaker has been switched off or during an operation in which the current flows through the circuit breaker so low that sufficient auxiliary energy is not generated to operate the overcurrent release. The energy for operating the electronic devices of the circuit breaker and the overcurrent release is to be taken from the network itself, which, apart from the short-term state (approx. 10 ms) after switching on or a current increase in the network via the aforementioned threshold value by the current sensor itself or if necessary, an additional energy converter is also easily possible. But even with sufficient

A microprocessor-based overcurrent release cannot supply auxiliary power immediately in the event of a short circuit, because the RESET routine of the microprocessor and the closing processing of the current measured values requires more than 10 ms. This time requirement is too high for current-limiting circuit breakers. For this reason, analog or analog-electronic bypass circuits are used, which enable the circuit breaker to react much more quickly.

According to EP 0 244 284 B1 mentioned, ironless current sensors of the Rogowski type are used for the bypass circuit. The tripping magnet is common to both types of tripping and is actuated via a common control circuit. Z-diodes are used as threshold elements in this solution as well as in EP 0 279 689.

A prerequisite for the desired rapid response of the circuit breaker to a short-circuit current is, in addition to the immediate delivery of a signal after a threshold value of the monitored current has been exceeded, that there is sufficient energy available to actuate the tripping magnet. This can be ensured that the electronic devices of the circuit breaker are powered by a constantly active auxiliary energy source (battery or the like). Often, however, an "autonomous" supply is preferred not only to the trip electronics, but also to the trip magnet from the network in which the circuit breaker is located. As a rule, the current transformers are then used for the energy supply, which also supply the measured values of the current, or separate "energy transformers" are installed in the circuit breaker. Obviously, these devices only provide auxiliary energy when the current flowing through the circuit breaker exceeds a certain minimum value. In the switch with electronic release shown in US Pat. No. 4,104,601, a direct actuation of the tripping magnet by magnetic influence is provided to accelerate the tripping at high short-circuit currents, with which an all-pole tripping can be effected. For this purpose, the magnetic field of the main current path is brought to bear on the holding magnetic field of the tripping magnet and, in the case of high overcurrents, it drops. The solution requires the spatial proximity of the main current path and the tripping magnet, which can only be achieved with a small number of switchgear designs (MCCB).

The invention is based on the object of specifying a bypass circuit for the trigger of a low-voltage circuit breaker which ensures a high level of safety against tripping in the event of short circuits.

According to the invention the object is achieved by the features of claim 1. Appropriate configurations are the subject of the subclaims.

Thereafter, the current sensors provided for operating the bypass circuit are designed as current transformers with an output power sufficient to actuate a release magnet when a short-circuit current flows.

The solution creates a completely independent circuit for instantaneous triggering of the switch contacts. This means that the release energy is provided, the response threshold is dimensioned and the contacts are converted into a mechanical movement by means that are neither partially nor wholly part of the normal release system. If a separate release magnet is provided, the most favorable design of the components and is obtained the shortest trigger delay. However, the release magnet available for the electronic overcurrent release can also be used in a version with a second winding for release by the bypass circuit.

The effort for the second tripping system is surprisingly low, since it is only a matter of detecting very high currents with an uncritical tolerance and therefore the current transformer in particular can have a very simple structure. The magnetic circuit can be open, e.g. B. as a rod-shaped core.

The evaluation circuit can have a correspondingly simple structure. It consists, for example, of a rectifier, a capacitor and a threshold circuit controlling the state of charge of the capacitor.

The bypass circuit can be short-circuited during normal operation of the overcurrent release. As a result, it is put out of operation and therefore cannot cause faulty tripping if electromagnetic interference occurs.

The invention is to be explained in more detail below with the aid of an exemplary embodiment.

The drawing shows a phase of a three-phase overcurrent release system of a low-voltage circuit breaker with a set of current sensors 1 combined from Rogowski coils and energy andern, a digital electronic overcurrent release 2, consisting of a microprocessor including reset generator, a power supply, the measurement signal processing and the trip circuit, which sends a signal to one in the event of a detected overcurrent in a monitored network Trigger magnet Fl of the low-voltage circuit breaker.

The bypass circuit 4 is fed from a separate current sensor 3, which is designed as an energy-supplying current transformer and is constructed as simply as possible. Its cores can e.g. B. be magnetically open (rod cores). The bypass circuit 4 comprises a bridge rectifier and a capacitor C to be charged by the latter. A threshold circuit 5 monitors the state of charge of the capacitor C. As soon as a sufficient charging voltage has been reached at the capacitor C, an electronic switch V2 is closed and thereby the energy stored in the capacitor C. a second trigger magnet F2 supplied. An advantage of using the separate trigger magnets F1 and F2 is the possibility of optimally adapting them electrically and magnetically to the energy available for triggering, and thus, in particular with regard to the second trigger magnet F2, a particularly low trigger delay with a more favorable dimensioning of the current sensor 3 and the components of the bypass

To achieve circuit 4.

As a further possibility, a common trigger magnet F3 is indicated in dash-dotted lines in the figure and has separate windings for the two trigger paths. This means that there are separate circuits for both types of tripping, but which use a common mechanical-magnetic path

The bypass circuit 4 thus works completely independently of the microprocessor-based electronic overcurrent release

Second In normal operating conditions, ie after the evaluation time of about 10 ms has elapsed, the bypass circuit 4 can be short-circuited by the transistor VI. This means that it is ineffective and cannot interfere with overcurrent release 2.

Claims

claims

1. Bypass circuit (4) for the electronic overcurrent release (2) of a current-limiting low-voltage circuit breaker with separate current sensors (1; 3) for the electronic overcurrent release (2) and for the bypass circuit (4) and with a tripping magnet (Fl ) to release an energy store of the circuit breaker, characterized in that the current sensors (3) provided for operating the bypass circuit (4) are designed as current transformers with an output power sufficient to actuate a release magnet (F2; F3) when a short-circuit current flows.

2. Bypass circuit according to claim 1, characterized in that between the current sensors (3) of the bypass circuit (4) and the trigger magnet (F2), a charging circuit for a capacitor (C) and a voltage of the capacitor (C) monitoring threshold circuit (5) Release of a discharge of the capacitor (C) on the release magnet (F2, F3) is switched with sufficient charge.

3. Bypass circuit according to claim 1 or 2, characterized in that the bypass circuit (4) contains a short-circuiter (VI) which can be controlled by the electronic overcurrent release (2) for deactivating the bypass circuit (4) in the region to be sold by the electronic overcurrent release (2). working currents.

4. bypass circuit according to one of claims 1 to 3, characterized in that a common tripping magnet (F3) for triggering the circuit breaker by the electronic overcurrent release (2) and bypass circuit (4) is provided and that the tripping magnet (F3) separate windings for both triggers.

5. Bypass circuit according to one of claims 1 to 3, d a d u r c h g e k e n n z e i c h n e t that for the tripping of the circuit breaker by the electronic overcurrent release (2) and by the bypass circuit (4) separate release magnets (Fl, F2) are provided.

6. Bypass circuit according to one of the preceding claims, d a d u r c h g e k e n n z e i c h n e t that the current sensors designed as current transformers (3) have a magnetically open iron circuit.