DE1268730B - Circuit arrangement for removing the volatile component of an electrical quantity composed of a volatile and a stationary component, preferably for a selective protection device for monitoring an electrical network - Google Patents

Description

Circuit arrangement for removing the volatile component of a electrical components composed of a volatile and a stationary component Size, preferably for a selective protection device for monitoring an electrical Network The invention is concerned with circuitry for removal a volatile component one of a volatile and a stationary component composite electrical quantity. As the theory of linear systems teaches, can the settling of all electrical quantities of these systems under any initial conditions can be represented mathematically as the sum of two time functions, one of which as a volatile component with a time constant peculiar to the respective system gradually disappears while the other as a stationary component from the switching instant in a constant manner of the impressed force that z. B. is a voltage, follows. It can also be demonstrated that the effect of such switching operations in linear systems, which are summarized as short-circuiting of nodes or let the separation of meshes be marked, always represented mathematically in this way can be as if an external force were the relevant electrical quantity of the system, that is, a voltage or a current in an electrical network from the moment of switching to add to zero. Even compensation processes as a result of the switching operations just mentioned can thus be composed of a volatile and a stationary component be understood.

In the context of electrical selective protection devices for electrical networks, it is significant that the interconnections of generators, transformers and lines containing networks with impressed, generally multiphase voltages, which are of interest in this context, are also to be referred to as linear systems. Therefore, short-circuits between the phases or to earth cause equalization processes, especially in the currents, so that these short-circuit currents can be broken down into a volatile component if and a stationary component i5 according to the following relationship: Here 10 = direct current amplitude at the beginning of the short circuit, I = alternating current amplitude (peak value), rx = random phase of the current i at the beginning of the short circuit, Time constant of the direct current element, XG = reactance of the generator feeding the network, XN = reactance of the network, RG = ohmic resistance of the generator, RN = ohmic resistance of the network. According to the above explanations, the direct current amplitude 10, at the start of the short circuit, can never be greater than the peak value f of the alternating current amplitude.

It can be seen that the volatile component of the short-circuit current, including, in this context, in general the one that occurs in the event of a fault, compared to the normal operating current, increased current in the network to be monitored is to be understood when evaluating the short-circuit current in a selective protection device is very undesirable. Uses the selective protection device as a criterion for the Monitoring of the network assigned to it, for example, the phase angle between Voltage and current on the line and should the selective protection device in case of over or If a certain phase angle falls below a triggering or signaling cause, the occurrence of the volatile component in the short-circuit current can one simulate wrong phase angle of the two electrical quantities in such a way that the network to be monitored is triggered incorrectly. Furthermore, the volatile Component i f, as equation (1) shows, for evaluation in a selective protection device not. suitable, because they are from the random phase of failure onset depends and for the case a = 0 does not exist. In summary, it can therefore be stated that that the volatile component seen from the metrological point of view - with below The term “measurement technology” does not only mean the selective protection technology should be - represents a decaying interfering signal, while the stationary one Component of the electrical quantity forms the useful signal.

These statements show that there is a need for a circuit arrangement for removing the volatile component one of a volatile and a stationary component Component composite electrical measured variable is, preferably for one Selective protection device for monitoring an electrical network. While the above-mentioned ones based on the presence of the volatile component So far tried to avoid difficulties in selective protection devices by that the volatile component which may occur is reduced Half waves «in the device or waits until the equalization process has subsided, the circuit arrangement according to the invention is characterized in that that it contains two resistors, one of which is resistance to the electrical one Measured variable in a circuit via a stationary component suppressing Filter network is fed, so that at him one of the volatile components corresponding electrical voltage is created while the other resistor is not connected fed by filters with the electrical measured variable in a further circuit so that an electrical voltage corresponding to the electrical measured variable is applied to it arises, and that the two voltages to obtain the stationary component are switched against each other. When using the example of the invention Circuit arrangement in the context of selective protection is the protective device the stationary one obtained as the difference between the electrical quantity and the volatile component Component supplied.

Although it is already known a circuit arrangement by means of eliminates the harmonics generated by a voltage source other than the useful frequency can, however, this is done according to the principle of negative feedback by adding to the load connected to the voltage source a voltage is removed and over a filter network blocking the useful frequency is fed to an amplifier; the output voltage generated by the amplifier is converted into that of the voltage source and the circuit formed by the load and compensates for the undesired Harmonics. As a result, a tension occurs at the load which is largely dependent on unwanted harmonics is freed.

The elimination of the undesired harmonics is essential in this circuit arrangement depends on the gain of the amplifier and the attenuation of the filter; to the To suppress unwanted harmonics, gain and attenuation must be large will. The elimination of the undesired harmonics is in the known circuit arrangement consequently largely dependent on the presence of an amplifier with the greatest possible gain.

In another known circuit arrangement for suppression for example, the ripple of a rectified current is also the Electrical quantity to be investigated fed into two parallel circuits, whereby A filter network is provided in one of these circles, but takes place in this Circuit arrangement the suppression of the disturbance variable using a different one Principle and other means than in the circuit arrangement according to the invention.

This is because the filters in this known circuit arrangement are of this type designed that at a given frequency of the ripple causing component the electrical size of this component in the one parallel circuit by 180 ° is rotated in phase. Since in the second parallel circuit of the known circuit arrangement only one ohmic resistor is provided, the electrical Size in its entirety, d. H. the uniform size and the one causing the ripple Transfer component in phase. The two parallel circuits are at the input of the load interconnected again, so that the transmitted over the two parallel circuits Add the proportions of the electrical quantity. On the basis of the This results in a phase rotation of the component causing the waviness by 180 ° an electrical variable at the input of the load in the known circuit arrangement, which has a significantly lower ripple than the original electrical quantity having.

Disadvantageous in terms of removing a volatile component is this known circuit arrangement insofar as the phase shift of a Filter depends on the square of the frequency. Should therefore by means of the known Circuit arrangement not only one harmonic, but several harmonics at the same time are suppressed, this can only be achieved to a limited extent by the Filter network is tuned to the frequency of the harmonics that are predominant is. In the case of an electrical variable with a frequency mixture, it can therefore be do not completely suppress this frequency mixture in the known circuit arrangement. The known circuit arrangement is therefore for removing a volatile component, which is known to represent a frequency mixture, is not suitable.

The circuit arrangement according to the invention is based on the following knowledge: In order to make it possible to estimate the interference signal, ie the volatile component, in relation to the stationary component representing the useful signal, the spectral function of the volatile component is considered with p = complex frequency, Le = Laplace transformation, and receives for the envelope curve the amounts plotted as a function of the angular frequency c,) If the envelope curve is normalized by dividing relation (3) by the value for 0 resulting from it, the result is: The range corresponds to the values of the time constant rN that occur in practice in electrical networks In Fig. 1 shows the course of equation (4) for five values of r ″ lying in the range (5). The diagram shows that at the point (o = 314 sec- ', ie 50 Hz, i.e. the mains frequency and thus the Frequency of the stationary component, the amplitude of the volatile component, i.e. the interference spectrum, has decayed to at least 30% of the value for 0 even in the worst case.

This fact allows that after filtering out the frequency the portion having the stationary component obtained filtered electrical Size as a volatile component and that obtained by subtracting the volatile component Component Quantity obtained from the electrical quantity as a stationary component to call.

To explain the circuit arrangement according to the invention, several exemplary embodiments are shown in the figures, of which FIG. 2 shows an embodiment in which the two resistors R 1 and R 2 expediently form a series circuit. They are each in a circuit I and II, of which the one labeled I via the filter network F. which is impermeable to the frequency of the stationary component, ie generally 50 Hz, and the one labeled 1I without the interposition of filters with the electrical quantity e or a current i driven by it is fed. The two circuits I and 1I contain the common current path 1 connected to the connection point of the two resistors R1 and R2, through which the currents in both circuits flow in the same direction. The volatile component ef of the electrical variable e is the voltage across the resistor R 1 in the first circuit I, while the stationary component is the total voltage across both resistors, which represents the differential voltage due to the interconnection of the voltages e and ef.

The resistor R 3 is expediently adjustable and is used for adaptation of the circuit II to the resistance of the filter network F.

Like F i g. 3 shows, the filter network F can have amplifiers V or downstream. They have the advantage that they have disruptive repercussions the energy source can be reduced.

As shown in FIG. 4 shows the filter network F in the negative feedback branch of the amplifier V. This type of circuit will be used when the Amplifier is provided with a negative feedback anyway.

The series connection of the resistors R1 and R2 can in turn form the input resistance of an amplifier, which can also be a so-called integration amplifier. The use of an integration amplifier is of interest if the electrical quantity e is the open circuit voltage of an ironless current transformer or an air-gap transformer, which is one of the derivatives of the primary current i emits a proportional secondary variable. F i g. 5 shows such an integration amplifier.

In Fig. G, a filter network F is specified, which in this embodiment is designed as a blocking circuit formed from the capacitance C and the inductance L, tuned to the frequency of the stationary component of the electrical variable e, which is in series with the resistor R 1 . One could also arrange an appropriately sized series circuit parallel to the resistor R 1.

It is important that the filter network in a known manner a has short running and settling times.

The in Fig. 7 reproduced oscillogram shows the effect of the method according to the invention and the circuit arrangement described for carrying out this method. The transient variable e is broken down into the volatile component ef, which has practically subsided after several periods of the network frequency, and the stationary component it is broken down in the manner described. The quality of the decomposition or the accuracy of the correspondence between the electrical quantities obtained by the decomposition on the one hand and the actually existing components of the electrical quantity c on the other hand is supported by the fact that when the volatile component ef has practically subsided, the stationary component is practically with the quantity e matches.

The invention offers the advantageous possibility of taking measurements Use of a compound composed of a volatile and a stationary component electrical quantities independently of the volatile component. These Possibility is particularly important in the context of selective protection in which - as shown - the volatile component occurs as a real disturbance variable. But it is notes that the invention does not relate to the decomposition of an electrical quantity into its volatile and their stationary components especially in the context of selective protection is limited. The invention can also be applied analogously to non-linear networks L °, n use. Furthermore, the stationary component need not only contain one frequency, but can deviate from the sinusoidal shape and accordingly a more or less wide one Own frequency spectrum. Then appropriately broadband filter networks must be used are provided.

Claims (9)

Claims: 1. Circuit arrangement for removing the volatile Component one composed of a volatile and a stationary component electrical. Measured variable, preferably for a selective protection device for monitoring an electrical network, characterized in that it has two resistors Contains, of which one resistance with the electrical measured variable in a circuit is fed via a filter network that suppresses the stationary component, so that at him a electrical corresponding to the volatile component Voltage arises while the other resistor does not use filters is fed with the electrical measured variable in a further circuit, so that an electrical voltage corresponding to the electrical measurand arises on it, and that the two voltages for the recovery of the stationary component are mutually exclusive are switched. 2. Circuit arrangement according to claim 1, characterized in that that the circuits have a common, at the connection point of the two resistors connected, through which the currents in both circuits flow in the same direction Contained current path and that as a volatile component the voltage than in the first Resistance lying in the circuit and the total voltage as a stationary component arises at both resistors. 3. Circuit arrangement according to Claim 1 or 2, thereby characterized in that amplifiers are assigned to the filter network. 4. Circuit arrangement according to one of claims 1 to 3, characterized in that the two resistors form the input resistance of an amplifier. 5. Circuit arrangement according to claim 4, characterized in that the amplifier is an integration amplifier. 6th Circuit arrangement according to one of Claims 1 to 3, characterized in that the filter network is tuned to the frequency of the stationary component, is in series with the first resistor parallel resonant circuit. 7. Circuit arrangement according to one of claims 1 to 5, characterized in that the filter network one tuned to the frequency of the stationary component, parallel to the first Resistance is a series resonant circuit. B. Circuit arrangement according to one of the Claims 1 to 7, characterized in that the filter network has a small running and- has settling time. 9. Circuit arrangement according to one of claims 3 to 8, characterized in that the filter network is arranged in the negative feedback branch of the amplifier. Contemplated publications USA.- Patent No. 1 792 001. Proc. IRE, 1949, pp. 1115 to 1119.