DE591357C - Voltage rotating field separator - Google Patents

Description

Voltage rotating field separator There are circuits for the decomposition of a asymmetrical three-phase voltage system in two opposite symmetrical Systems have become known in which there is a split of two or more Voltages of the three-phase network act in leading and lagging components, whereupon a resultant tension by combining suitable components is achieved which the co-rotating system or the opposing voltage system is equivalent to.

The voltage rotating field separator for three-phase systems described below is characterized by its simplicity in construction and its low power requirement from and above all by the fact that it is connected to the three-phase current lines or the associated Voltage transformers direct, d. H. galvanically, and thus connected without an intermediate converter can be. The chaining of the voltage circuits, which are mostly used for relays and Measuring equipment is necessary, does not need to be solved. The rotating field separator is further characterized in that the relay or display device for the counter-rotating Voltage system on the one hand is connected to a point that has the potential of a Corner of the voltage triangle, and on the other hand at a point of an art circuit is connected, which has the same potential as long as the mains voltages are symmetrical. But if the relay is on the co-rotating component of the voltage should address, you can do this by simply interchanging two, known per se Reach voltage leads to the art circuit. With completely symmetrical Mains then a voltage is applied to the relay, which is the difference between two interlinked Line voltages, d. H. i.e. 13 times the value of a line voltage.

The figures serve to explain the invention. In Fig. Z there are three Connections R, S, T for the three-phase network or for corresponding terminals of the secondary windings drawn by voltage converters. One leads from the connection marked T Connection to the terminal marked S via a choke coil L1, an ohmic one Resistance R1 and a capacitance Cl. The partial voltages which are applied to L1, Rl and Cl omitted, form two sides with each other with perfectly symmetrical mains voltages of an equilateral triangle. The connection point between the resistor R1 and the capacitance Cl thereby receives a potential which is equal to that of the connection R. As a result, speaks in a symmetrical network between the network connection R and Device G connected to this connection point does not turn on. By swapping two Network connections are known from which to the opposite saving system responsive device G one which responds to the live voltage system. The interlinked voltages prevail between the connections R, S, T. The circuit the voltage converter not shown in FIG can be arbitrary, they can be, for. B. also be connected in V-circuit. If you switch the transducers so that their common point is the connection point S. is, then one achieves such a distribution of the wander power that the apparent power of the converter lying between the phases R and S is zero, during the between the phases S and T converter, the power dissipation of the circuit alone wearing. If you swap the connection points for the converters, you get a circuit in which the two converters connected to V are loaded to the same extent like the converter of the circuit described above, which is located between phases T and S.

The task in one. Three-phase circuit a point a potential to issue which corresponds to a corner potential of the voltage triangle, can also can be solved in the manner shown in FIG. The voltage connections are again denoted by R, S, T. An ohmic resistor R2 and the primary winding W1 one Intermediate converter T1 are connected in series to the voltage between the connection points R, S. At the connection point T the display device or relay G is in series with the Secondary winding W2 of intermediate transformer T1 connected. One end of the winding W2 is also at the connection point S. The number of turns W1 and W2 of the intermediate converter Ti are related to one another as i, neglecting the loss corrections : 2.

The mode of operation of the arrangement is explained by FIG. 3. The voltage between the connections R, S is broken down into two components RK, ES by the ohmic resistance R1 and the inductive resistance of the winding W1 of the intermediate converter T. By doing. Circuit piece, which contains the display device G and is located between the connection points T and S, have two voltages. One corresponds to the voltage difference between the connection points S and T. The second is the secondary voltage of the intermediate converter Ti, ie the primary voltage SK (FIG. 3), multiplied by the transformation ratio of the intermediate converter. It has the same size as the voltage ST, but in the opposite direction. As a result, as long as the mains voltages are symmetrical, these two voltages cancel each other out, so that no current flows through the relay or display device G.

Claims (3)

P-1TrN T ANSPRL CIIE: x. Voltage rotating field separator for a three-phase network with a relay or measuring device for the opposite voltage system, characterized in that, that the relay is connected on the one hand to a point that has the potential of a Corner of the voltage triangle of the network, and on the other hand at a point one Circuit is connected with the help of this corner of the voltage triangle the opposite triangle is brought to the same potential by tensioning the network is as long as the line voltages are symmetrical. 2. Arrangement according to claim i, characterized by a voltage divider circuit with Ohmic. Resistance of such a size that the mains voltage applied to the voltage divider circuit in two components enclosing an angle of 6o 'is decomposed. 3. Arrangement according to claim i, characterized in that a mains voltage is broken down into components becomes, one of which, by transformation, is equal to a second triangular voltage of the symmetrical network is made.