DE697295C - Malfunction recorder for electrical networks in which a relay dependent on the malfunction increases the speed of the recording strip - Google Patents

Description

Fault recorder for electrical networks in which one of the faults dependent relay increases the running speed of the recording strip for recording the course of the variables in an electrical network during a fault are so-called Fault recorder known, which in particular reproduce the voltage curve. In order to the consumption of recording paper is as low as possible, its running speed becomes in normal operation kept relatively small and only in the event of a fault on such The amount is increased so that the course of the disturbance can be seen clearly enough.

In the known designs, the registration strip is switched over from the lower to the higher speed by a relay that is only depends on the absolute stress level, d. H. when exceeding or falling below of a previously set setpoint. This has the disadvantage that there are also switchovers occur when there are no errors in the network, but only as a result corresponding voltage drops occur during control processes.

To avoid such false triggers, which lead to increased consumption of recording paper, one was forced to use one according to the normal Voltage fluctuations to make wide setting of the relay. But that was The claim, eh, feel down, g, it last, and the relay spoke at short-term Interferences no longer appear.

There are also fault recorders -been known in which the Switching of the running speed of the registration strip by a system of oscillating springs or pendulums interacting with contacts is initiated, wherein the springs or pendulums to the possibly occurring frequencies of the processes, how vibrations of the machines with each other or resonance processes are coordinated.

The invention relates to a fault recorder for electrical networks, in which a relay dependent on the fault determines the running speed of the recording strip increased when the disturbance occurs. According to the invention, the relay is protected from the voltage drop operated on a resistor, which may be rectified and smoothed Supply voltage to a capacitor with bleeder resistor, these switching elements are dimensioned so that the relay when the mains voltage drops on responds to a predetermined value only when the rate of change of the Mains voltage greater than the regulated speed of the voltage regulating device tion is.

The invention is shown in the drawing; for example illustrated.

Fig. 1 shows an embodiment of the invention. A DC voltage is fed to a capacitor Ct through a series resistor to which a polarized Relay is arranged. A resistor R1 is shunted to the capacitor C1. The resistor R1 has such an ohmic value in relation to the resistance R, that with a slow voltage drop, the capacitor C1 to the new lower Potential brought by a discharge current as that corresponding to its charge which takes its way via the resistor R1. With rapid voltage drops however, in addition to the discharge current, a discharge current also flows through the resistor R1 via the resistor R, which has the opposite direction as the charging current of the capacitor. As a result, the relay responds and thus actuates the switching device.

In Fig. 2 is an embodiment of the invention for AC networks shown.

Here it is necessary to connect the AC voltage via a rectifier G to switch.

A capacitor is used to smooth out the DC voltage obtained in this way C2 connected in parallel with the rectified voltage.

A resistor R2, which also bridges the DC voltage, provides then together with the resistor R represents the discharge circuit for the capacitor C1. This discharge circuit must therefore be matched to the resistance so that only with correspondingly rapid voltage drops does the discharge current make its way over the resistances R, R2 takes.

In Fig. 3 an embodiment example for alternating current networks is shown, in which the response device A is a grid-controlled discharge vessel. Of the The lattice circuit of the discharge vessel is accordingly connected to the resistor R. aside from that a bias voltage is inserted into the grid circuit, which is applied to a DC voltage source or, according to the exemplary embodiment, is removed from a resistor R8, which is shown in Series to resistor R1, parallel to capacitor C1. The bias is chosen so that the ignition potential only occurs in the discharge vessel when the voltage change in the network is both its size and its speed after exceeds the predetermined level. In this case, the voltage drop will Overcome at resistor R3 by the voltage at resistor R and accordingly -ein the response of the tube caused tittérpotential.

In the anode circuit of the tube there is a resistor Ro, an anode current source and an intermediate relay P which actuates the switching device. The heating current the tube, like the heating current of a rectifier tube G, is supplied by a converter W supplied, which at the same time also has a winding to power the device the rectifier E has.

So that the facility returns to its original state after a fault State is reset, there is a switch-off contact (not shown) in the anode circuit arranged, which is open briefly a certain time after responding. A discharge vessel with a gas or vapor filling is expediently used used.

For setting the rate of change required for response the mains voltage can be the series resistor R1 or the parallel resistor R or make both variable, to set the absolute required for response Voltage drop the grid bias, i.e. the resistor R1.

In three-phase networks it is possible to use only a single discharge vessel A and a relay P to control the switching device. A corresponding one The embodiment is shown in Fig. 4. Here is one of the phase numbers of the Network corresponding number of capacitors and parallel resistors as well as provided in the embodiment of Fig. 3. The capacitors C1 are, however interconnected to a star point, and this star point is via a common Resistance R led.

Only the voltage drop in this resistor is to be actuated of the tube A is decisive, so that this tube is only in accordance with the exemplary embodiment 3 needs to be switched. The resistances are matched in such a way that that the response only takes place if under the required response conditions a sufficiently large discharge current is produced by one of the capacitors Ct.

Claims (6)

PATENT CLAIMS: I. Fault recorder for electrical networks, at to which a relay dependent on the fault determines the speed at which the recording strip runs upon entry the disturbance increased, characterized in that the Relay is actuated by the voltage drop in a resistor (R), which, if applicable rectified and smoothed mains voltage a capacitor (C1) with bleeder resistor (R1) supplies, with such a dimensioning of these switching elements, that the relay only responds when the mains voltage drops to a predetermined value, if the rate of change of the mains voltage is greater than the regulating rate the voltage regulator is. 2. Disturbance recorder according to claim I, characterized in that A grid-controlled discharge vessel with a grid serves as the response relay (A) is influenced by the voltage drop of the series resistor (R). 3. Disturbance recorder according to claim I and 2, characterized in that that the lattice nerve, orspall! nun1g of the discharge vessel to a certain size of the Voltage drop across the resistor (R) is set. 4. fault recorder according to claim 3, characterized in that the voltage drop of a resistor (R3) is used as a bias voltage, which is in the by the discharge circuit of the capacitor (C1) formed by the bleeder resistor (R1). 5. Disturbance recorder according to claim 1 to 4, characterized in that that for setting the rate of change required for the response Line voltage a variable bleeder resistor (R2) - one to smooth the rectified AC current provided capacitor (C2) is used. 6. fault recorder according to claim I to 5 for three-phase networks, characterized characterized in that three capacitors (cit) with bleeder resistors (R1) to one Star connected and led to a common series resistor (R).