DE2742965A1 - DC circuit breaker unit for high voltage systems - having circuit breaker, oscillator and metal oxide varistor in parallel - Google Patents

Abstract

D.c. circuit breaker equipment has a circuit breaker, an oscillator circuit contg. a capacitor and a coil, a switch, which connects the circuit breaker in parallel with the oscillator circuit when this is opened, and a resistor for charging the capacitor. The novelty is that a varistor (RN) contg. a sintered metal oxide mixt. is connected in parallel to the oscillator circuit. This pref. consists of ZnO, MgO, CoO, NiO, Sb2O3 or Bi2O3. The circuit breaker is suitable for d.c. transmission systems of high voltage and large capacity. The construction is simple and the circuit can be broken rapidly.

Description

Device for interrupting a direct current circuit

The invention relates to a device for interrupting a direct current circuit, those for use in high voltage and DC power transmission systems large capacity is suitable.

In the case of a breaker in an AC circuit, an between separated contacts ignited arc extinguished when the current goes through zero. In a direct current network, however, the current and voltage do not go through zero, and it does therefore current and voltage must be greatly reduced. For this purpose are numerous devices have been proposed.

Fig. 1 shows an example of such a device in which a Circuit breaker CB in the form of a vacuum switch or a circuit breaker, in which an arc-extinguishing medium such as SF6, air, oil, etc. is used, is connected in series with a direct current line, with an oscillator circuit with a capacitor C, a coil L and a switch S in parallel with the circuit breaker CB is switched. If the Circuit breaker CB is opened, the switch S is closed to an oscillating discharge current of the capacitor C by the arc burning between the contacts of the circuit breaker CB to be allowed to flow, whereby a zero crossing is generated in the current to be interrupted will.

Fig. 2 shows part of a direct current transmission system below Use of a circuit breaking device according to FIG. 1, wherein Tr is a Transformer, Re a rectifier or converter, Ls a smoothing reactor and F denotes a filter with a capacitor. When the direct current I through the high frequency oscillating discharge current is interrupted in the smoothing reactor LS the energy 1/2 LS I2 stored, where LS means the inductance. These Energy charges the capacitor of filter F to an excessively high voltage. In order to avoid such excessive tension, there is a device shown in FIG has been developed, in which R is a resistor for charging the capacitor C, R a non-linear resistance element made of silicon carbide as characteristic Element of an arrester and TR1, TR2, TR3 designate trigger column, i.e. arc column, which are provided with trigger electrodes, as described in detail later is. Simultaneously with the opening of the circuit breaker CB, the trigger gap becomes TG1 ignited, causing an oscillating over the arc of the circuit breaker CB Discharge current 10 flows through the arc and interrupts the current I. the excessive tension described above controls the trigger gap TG2, which eliminates the energy stored in the smoothing inductor through the not derived linear resistance element R5 and suppressed the excessive voltage will.

Thereafter, a direct current flows according to the direct voltage of the transmission line through the trigger gap TG2 and the non-linear resistance element Rs. When the trigger gap TG3 is driven after suppressing the excessive voltage is, the oscillating discharge current I1 of the capacitor C flows over both trigger columns TG2 and TG3, whereby the current flowing through the trigger gap TG2 is interrupted will. When the insulation strength of the trigger gap TG2 is reached again, the non-linear resistance element Rs is isolated from the transmission line.

Another DC interrupt device, as shown in Fig.

4 has also been developed in which a series connection with a non-linear resistance element Rs and a circuit breaker CB1 are connected in parallel with a DC circuit breaker CB. When the circuit breaker CB is opened, appears on the disconnected contacts of the circuit breaker a high cut-off voltage, so that the current I to be interrupted becomes non-linear Resistance element Rs is transmitted.

The current I1 flowing through the resistance element Rs is smaller than the current to be interrupted. Then the circuit breaker CB1 is opened, to interrupt the current I1. Since at that time the current r1 through the resistance element Rs is limited, the interruption is easy. When the circuit breaker device according to Figure 4 in the direct current transmission system according to Fig. 2 is used is, the energy stored in the smoothing choke coil LS is caused by the arcs the circuit breakers CB and CB1 and the resistance element 4 discharged.

DC breaker devices are generally on both Ends connected to a direct current transmission line as shown in FIG is in which DCCB1 and DCCB2 DC breaker devices, LS1 and LS2 Smoothing reactors, F1 and F2 filters, Re1 a rectifier (or converter) and Re2 are a converter (or rectifier). When a DC breaker device is used according to FIG. 3 and if an error occurs in the transmission line, becomes the excessive voltage caused by the smoothing choke coil LS1 is suppressed by the associated non-linear resistance element Rs, however that caused by the smoothing choke coil LS2 at the opposite end excessive voltage cannot be suppressed because of the circuit breaker DCCB2 does not open. On the other hand, when the circuit breaker device 4 is used in a direct current transmission line, the Energy of both smoothing reactors LS1 and LS2 are absorbed. With the in Fig. 4 shown construction but results in a complicated and expensive construction, as it is necessary to interrupt the flow of current through the resistance element to use an additional circuit breaker CB2.

It is the object of the invention to provide an improved device for Interrupt to create a direct current circuit, the construction of which is simple and the one can quickly interrupt large DC currents at high voltages. This is according to the invention achieved in that in a device for interrupting a direct current circuit with a breaker, with one containing a capacitor and a coil Oscillator circuit, with a switching device, which when the breaker opens this connects the oscillator circuit in parallel, and with a resistor for the Charging of the capacitor, parallel to the oscillator circuit, a non-linear one Resistor is connected, which contains a sintered metal oxide mixture. These Metal oxide mixture can consist of ZnO, MgO, CoO, NiO, Sb2O3 or Bs 203.

The invention is illustrated below with reference to the drawing of exemplary embodiments explained in more detail. The drawing shows: FIG. 1: a circuit diagram of a direct current interrupter device with an arc extinguishing circuit according to the prior art, FIG. 2: a circuit diagram, which shows one end of a direct current transmission line, the one shown in FIG Interrupter device is used, Fig. 3 circuit diagrams, which further known Examples of DC and 4: current interrupter devices are shown in FIG. 5: a circuit diagram a direct current transmission line, FIG. 6: a circuit diagram showing an exemplary embodiment of the invention shows Fig. 7: a graphic representation which shows the voltage-current characteristic of a non-linear resistance element, which is used in the embodiment of Fig. 6, and Fig. 8, circuit diagrams, which modified versions of the invention 9 and 10: represent.

In a preferred embodiment of the invention, as shown in As shown in Fig. 6, a main circuit breaker CB is in series with a conductor 10 connected to a direct current transmission line 1, and it is a series circuit from a non-linear resistance element RN and a trigger gap TG in parallel switched to the main circuit breaker CB. As is well known, there is a trigger gap a discharge gap, which is provided with a trigger electrode, which is close to a Slit electrode is arranged, with an arc between the slit electrodes is ignited when a trigger pulse is applied to the trigger electrode. One Oscillator circuit with a capacitor C and a choke coil L is in parallel switched to the non-linear resistance element RN, and it is a resistor R. for charging the capacitor C to the connection between the choke coil L and the trigger gap TG. The other end of the resistor R is with the other conductor 11 of the transmission line connected.

The invention is characterized by the use of a not linear resistance from a sintered metal oxide mixture.

According to an example, the mixture has the following composition: 87 up to 12 mol% ZnO, 12 to 8 mol% MeO (with MeO at least one of the constituents MgO, CoO and NiO), 1 to 30 mol% So203 and 0.5 to 10% by weight BiLO 23 2 3 According to another example, the mixture has the following composition: 0.08 up to 4.0 mol% Bi2O3, 0.05 to 4.5 mol% CoO, 0.07 to 5.0 mol% Mno, 0.05 to 6.0 Mol% Sb2O3 and remainder ZnO. Many other similar metal oxide resistors with no linear characteristic are well known. Such a non-linear resistance has a voltage-current characteristic as shown in FIG. As can be seen the resistance has a considerable non-linear or negative resistance characteristic, so that when the voltage across the resistor exceeds a critical value E, the current 0 increases sharply, while as long as the line voltage E is lower than the critical value is E, a negligible 0 value current on the order of magnitude of milliamps flowing. In addition, the resistor RN is not thermally damaged, and not even if a normal DC voltage E, which is only slightly lower than the critical value E is continuously supplied. For this reason, the Resistor RN is not thermally damaged, although it is connected in parallel with capacitor C. which is charged to the line voltage E through the resistor R. Although the charge on capacitor C normally discharges through resistor RN, such a discharge current is small because the line voltage E is chosen so that it is lower than the critical voltage Eo, and the current is supplemented through the charging current through the resistance R.

When a short circuit or other abnormal condition in the DC transmission line occurs, the circuit breaker CB is opened and it is simultaneously the trigger gap TG causes a discharge. Then the arc of the Circuit breaker CB by the oscillating discharge current lo in one erased in such a manner as described above. Because of the in the Smoothing choke coil stored energy is applied to a steep switching voltage applied to the non-linear resistance, which is greater than the critical voltage Eo, which transfers the current I to the non-linear resistor RN. If in individual in a direct current transmission system, as shown in Fig. 5, after the dissipation of the energy stored in the smoothing choke coils LS1 and LS2, this is 1/2 LS1 12+ 1 / 2LS212, through which the non-linear resistance RN has occurred, the current flowing through this resistor decreases to a low value. It Then a current flows through the trigger gap TG, which is equal to the sum of this small Value and the current flowing through the charging circuit. Such a small amount of electricity can be easily cleared by the trigger gap, and it is the DC circuit completely interrupted.

The above description is of a consistent bug, however is at an internal defect as shown by a broken line in FIG. 5 is the energy consumed by the non-linear resistor that is in the inductor LS 1 stored Energy, and it's the electricity that is to be interrupted, the residual current of the non-linear resistor.

Since the current that is to be interrupted by the trigger gap, is small, i.e. on the order of 1 amp, the trigger gap can be through a simple mechanical switch can be replaced.

As in the above-described DC breaker device As the resistance of the non-linear resistor decreases, the voltage is above the resistance is small when the current to be interrupted is transferred here. This is desirable because it is possible to control the excessive voltage of the DC transmission system to fight. However, when the resistance value of the non-linear resistor is small is, the current normally flowing through it from the capacitor becomes excessive large, thereby damaging the non-linear resistance.

In a modified embodiment according to FIG. 8, there is a resistor R2 connected in parallel to a non-linear resistor RN. By selecting the The value of the resistor R2 is an order of magnitude smaller than the non-linear resistance it is possible to divide the DC voltage between the resistors R and R2. if R = R2, only half of the DC voltage is fed to the non-linear resistor, thereby reducing the current normally flowing through it. With others Words it is possible to measure the resistance value of the non-linear resistance at normal Reduce tension.

In the case shown in Fig. 9, the trigger gap contains TG by a distance arranged main discharge electrodes 1 and 2 and a trigger electrode 3, the is arranged near the main electrode 1 which is connected to the line. In in this case one terminal of the non-linear resistor RN is connected to the trigger electrode 3 connected so that this electrode by the switching voltage on the circuit breaker CB is operated. It is readily apparent that this embodiment in the works in the same way as the embodiment according to FIG. 6, but that it is advantageous in this respect is when it is not necessary to use a special current pulse source, which actuates the trigger electrode 3.

In another embodiment according to FIG. 10, a resistor R2 is parallel connected to the non-linear resistor RN, and there is a capacitor C2 across the main discharge electrode 1 and the trigger electrode 3 are switched. With this Arrangement becomes most of the arc voltage of the main electrode 1 and the Trigger electrode 3 pressed on, so that a large arc is generated between them can be, whereby an immediate response of the trigger gap ensures is.

With the various designs described above, it is possible to a non-linear resistance to the capacitor charging resistor R replace or a non-linear resistor to resistor R in parallel too switch.

L e r s e i t e

Claims (8)

PATENT CLAIMS Device for breaking a direct current circuit with a breaker, with one containing a capacitor and a coil Oscillator circuit, with a switching device, which when the breaker opens this connects the oscillator circuit in parallel, and with a resistor for charging of the capacitor, characterized in that parallel to the oscillator circuit (L, C) a non-linear 'resistor (RN) is connected, which is a sintered metal oxide mixture contains. 2. Device for interrupting a DC circuit according to claim 1, characterized in that the metal oxide mixture of ZnO, MgO, CoO, NiO, So 203 or Bi203. 3. Device for interrupting a DC circuit according to claim 1, characterized in that the switching device consists of a trigger gap (TG) with a pair of separate gap electrodes and a trigger electrode, which can ignite an arc between itself and one of the gap electrodes. 4. Device for interrupting a DC circuit according to claim 1, characterized in that the switching device consists of a mechanical switch consists. 5. Device for interrupting a DC circuit according to claim 1, characterized in that parallel to the non-linear resistor (RN) another Resistor (R2) is switched. 6. Device for interrupting a DC circuit according to claim 4, characterized in that one end of the non-linear resistor (RN) with the trigger electrode (3) is connected, while its other end is connected to one end of the breaker (CB) is connected. 7. Device for interrupting a DC circuit according to claim 6, characterized in that between the trigger electrode (3) and one of the gap electrodes (1,2) a capacitor (C2) is connected. 8. Device for interrupting a DC circuit according to claim 1, characterized in that the capacitor (C) charging resistor (R) is not linear resistance.