RU2641649C1 - Device for symmetrization and stabilization of three-phase voltage - Google Patents

Abstract

FIELD: electricity.SUBSTANCE: device for symmetrization and stabilization of three-phase voltage comprises three winding groups of three identical series-connected secondary windings of three single-phase transformers having by one primary winding. On the magnetic circuit of each transformer an additional winding with branches through an equal number of turns is placed, the beginning of the additional winding is connected to the beginning of the primary winding and the beginning of the farthest secondary winding of one of the winding groups. The end, beginning or any branch of the additional winding is connected to the corresponding input phase grip by means of the switching circuit at the signal of the control unit. The end of the primary winding is connected to the zero grip. The number of branches of the additional winding is not limited, and the number of turns should be four or more times smaller than that of the primary winding.EFFECT: expansion of functionality and improvement of the quality of the device.1 dwg

Description

The invention relates to power supply systems of electrical networks and distribution of electrical energy, and in particular to devices for eliminating or reducing asymmetry in multiphase networks, and can be used in three-phase electrical networks to reduce asymmetry and stabilize voltages.

A device for balancing the voltage of a three-phase network is known, which is a prototype that compensates for voltage asymmetry by geometric subtraction of the selected zero-sequence voltage from the voltages of all three phases, for which three groups of series-connected secondary windings of three step-down single-phase four-winding transformers with a transformation ratio of three are connected in series each in the wire of the corresponding phase so that geometric subtraction of lennogo on groups of serially connected secondary windings of said zero sequence voltage of the respective phase voltages and the primary windings of the transformers are connected in a star data and connected to the phase voltage (see. patent RU 2552377 C2, H02J 3/26, 18.07.2013).

A disadvantage of the known device is the inability to adjust the magnitude of the components of the direct sequence of voltage at its output, which may be required to compensate for voltage drops on the winding groups of serially connected secondary windings with an increase in load or with an insufficient value of these components in the input mains voltage due to a large voltage drop in supply line wires.

The technical result is to expand the functionality of the device without significantly increasing its overall dimensions and improving the quality of the functioning of the device due to the possibility of compensating for voltage drops at the impedances of the winding groups from series-connected secondary windings due to the load current flowing through them.

The specified technical result is achieved by the fact that in a device for balancing and stabilizing a three-phase voltage, containing three winding groups of three identical serially connected secondary windings of three single-phase transformers having one primary winding, an additional winding with branches through an equal number of turns is placed on the magnetic circuit of each transformer, the beginning of which joins the beginning of the primary winding and the beginning of the extreme secondary winding of one of the winding groups, the end, The start or branch of the auxiliary winding is connected by a signal from the control unit to the corresponding input phase terminal, the end of the primary winding is connected to the zero terminal, the number of turns of the additional winding must be four or more times less than the number of turns of the primary winding, and the number of branches of the additional winding not limited to.

In FIG. 1 is a schematic electrical diagram of a device for balancing and stabilizing a three-phase voltage, on which the following notation is made: 1 - control unit, 2 - switching circuit, 3 - input phase clamps of the device, 4 - output phase clamps of the device, 5 - power transformer, 6 - additional winding, 7 - secondary winding, 8 - primary winding, 9 - zero clamps of the device. The device includes three identical single-phase transformers 5. Each transformer has one primary winding 8, three identical secondary windings 7 and one additional winding 6. The number of turns of each of the secondary windings 7 is three times less than the number of turns of the primary winding 8. Corresponding secondary windings 7 (first, second and third, if assigned to them as part of transformers) are interconnected in series, forming three separate winding groups. The number of branches of the auxiliary winding 6 is arbitrary depending on the accuracy requirements for maintaining the voltage at the output of the device, and the number of turns of the winding 6 should be four or more times less than that of the primary winding. The beginning of the winding 6 is connected to the beginning of the primary winding 8 and the beginning of the extreme secondary winding 7 of one of the winding groups. The end, the beginning and all branches of the auxiliary winding 6 are connected to the corresponding switching circuit 2. Inside the switching circuit 2, the end, the beginning and all branches of the additional winding 6 can be individually electrically connected by switching with the corresponding input phase terminal, also connected to the switching circuit. The end of the primary winding 8 is connected to the zero terminal N. The switching control inside the switching circuit 2 is carried out by means of the control unit 1. The three-phase voltage balancing and stabilization device is connected to the network by terminals A1, B1, C1, N, and to the load by terminals A2, B2, C2 , N. On the circuit diagram of the device near the beginnings of the corresponding windings, points are shown.

A device for balancing and stabilizing a three-phase voltage operates as follows. On the primary winding of each transformer, a voltage is obtained equal to the geometric sum of the voltage on the auxiliary winding, depending on the number of sections included in the operation, and the phase voltage of the corresponding phase of the network. Unlike the prototype, at each output phase terminal of the device relative to the neutral wire, a voltage is obtained equal to the geometric difference of the voltage acting on the primary winding of the corresponding transformer and the voltage released on the corresponding winding group from the same series-connected secondary windings of the specified transformer. On each winding group of the secondary windings, as in the prototype, a zero-sequence voltage component is allocated, however, unlike the prototype, this is a component of the mains voltage corrected by the additional winding acting on the primary winding clamps. Thus, in the device, the asymmetric phase voltages are initially increased modulo by means of an additional winding by a certain number of percent, depending on the number of turns of this winding included in the work, and then they are balanced by geometric subtraction of the zero sequence components isolated on the winding groups from secondary windings. The switching of branches of the additional transformer windings is carried out by means of a switching circuit based on a signal from a control unit that controls the level of phase voltages at the output of a three-phase voltage balancing and stabilization device, and switching must occur simultaneously at the same positions, that is, always in each of the transformers depending on the level of phase the voltages at the output of the three-phase voltage balancing and stabilization device must be simultaneously activated dinakovye number of turns of the additional windings or by means of a switching circuit all additional winding should be withdrawn from work. The use of additional windings makes it possible to increase the components of the direct sequence of voltage at the output of the three-phase voltage balancing and stabilization device, which may be required to compensate for the voltage drops on the winding groups from the secondary windings when the load increases or when these components are insufficient in the input mains voltage due to a large drop voltage in the wires of the supply line, and ultimately increases the number of possible applications we consider th device, as well as the quality of its operation.

Claims (1)

A device for balancing and stabilizing a three-phase voltage, containing three winding groups of three identical series-connected secondary windings of three single-phase transformers having one primary winding, characterized in that an additional winding with branches through an equal number of turns is placed on the magnetic circuit of each transformer, the beginning of which is connected to the beginning of the primary winding and the beginning of the extreme secondary winding of one of the winding groups, the end, the beginning or branch of the additional windings by means of a switching circuit are connected to the corresponding input phase clamp by a signal from the control unit, the end of the primary winding is connected to the zero clamp, the number of turns of the additional winding must be four or more times less than the number of turns of the primary winding, and the number of branches of the additional winding is not limited.

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