RU2677244C1 - Electromagnetic compensator of current of third harmonic in three-phase four-wire networks - Google Patents

Abstract

FIELD: electrical engineering.SUBSTANCE: third-harmonic electromagnetic current compensator contains a three-phase half-wave rectifier, four current transformers, one of which is connected by its primary winding to a neutral wire, and the other three – in the phase wires of the network, characterized in that it additionally introduced a filter with a bandwidth of 150 Hz, three current relays and three circuits of series-connected capacitors and a resistor, the windings of the three current relays are connected in parallel with the secondary windings of three current transformers included in the phase conductors of the network, and series-connected disconnecting contacts of three current relays shunt the secondary winding of a current transformer connected to the neutral wire of the network, and parallel to the windings of three current relays are connected circuits of series-connected capacitor and resistor, the beginnings of the secondary windings of three current transformers included in the phase conductors of the network are connected to a common point and connected to the beginning of the secondary winding of the current transformer included in the neutral wire, and the ends of three current transformers included in the phase conductors of the network are connected to the anodes of a three-phase half-wave rectifier, cathodes of which are connected to a common point and connected through a filter with a bandwidth of 150 Hz to the end of the secondary winding of a current transformer included in the neutral wire of the network.EFFECT: improving the accuracy of the third harmonic compensation.1 cl, 1 dwg

Description

The invention relates to electrical engineering and can be used to improve the energy efficiency of three-phase four-wire networks by reducing additional losses of power and electricity from the flow of third harmonic currents.

A device is known for protecting the network from the effects of third harmonic currents (patent RU 2353040, IPC H02J 3/01, H02J 3/26, Bull. No. 11, 2009), consisting of a measuring transformer and a rectifier, into which three transreactors are introduced, the primary windings of which are included in the cut of the linear wires of the network, and the beginnings of their secondary windings form a common point with the end of the secondary winding of the measuring transformer, while the measuring transformer is made by a transreactor, and the rectifier is three-phase.

The disadvantages of this device are the large error of the transreactors and the weak suppression of the third harmonic current in the neutral wire of the network, as well as the possibility of the device working in overcompensation mode, as a result of which the low energy efficiency of suppressing the third harmonic currents.

The prototype is an electromagnetic compensator of the third harmonic of the electrical network (patent RU 2346370, IPC H02J 3/01, Bull. No. 4, 2009), containing a measuring current transformer, rectifier and converter, into which three current transformers are introduced, the primary windings of which are included in dissection of the linear wires of the network, and the beginnings of their secondary windings form a common point with the end of the secondary winding of the measuring current transformer, the ends of the secondary windings of the three current transformers through a rectifier are connected to a positive output of the converter, the negative output terminal of which is connected to the beginning of the secondary winding of the measuring current transformer, the primary winding of which is included in the neutral wire of the network, in addition, the rectifier is made three-phase, and its cathodes form a common point with the positive output terminal of the converter, and each of the rectifier anodes connected to the ends of the secondary windings of three current transformers.

The disadvantages of this device are the dependence of the value of the compensating current of the third harmonic on the magnitude of the current of the fundamental harmonic, thereby the possibility of the device operating in overcompensation mode, which reduces the efficiency of compensation of the current of the third harmonic.

The objective of the invention is to increase the compensation efficiency of the third harmonic current in a three-phase four-wire network.

EFFECT: increased accuracy of compensation of the third harmonic current due to the exclusion of the overcompensation mode, which improves the quality of electric energy, reduces the loss of active power and voltage loss in all elements of a three-phase four-wire network from the third harmonic current.

The technical result is achieved by an electromagnetic compensator of the third harmonic current in three-phase four-wire networks, containing a three-phase half-wave rectifier, four current transformers, one of which is connected with its primary winding to the neutral wire, and the other three to the phase wires of the network, into which an additional filter with a passband 150 Hz, three current relays and three circuits from a series-connected capacitor and resistor, while the windings of three current relays are connected in parallel with the secondary winding kam of three current transformers included in the phase wires of the network, and the serially connected disconnecting contacts of the three current relays bypass the secondary winding of the current transformer included in the neutral wire of the network, also, parallel to the windings of the three current relays are connected circuits of series-connected capacitor and resistor, while the beginning of the secondary windings of the three current transformers included in the phase wires of the network are connected to a common point and connected to the beginning of the secondary winding of the current transformer into the neutral wire, and the ends of the three current transformers included in the phase wires of the network are connected to the anodes of a three-phase half-wave rectifier, the cathodes of which are connected to a common point and connected through a filter with a passband of 150 Hz to the end of the secondary winding of the current transformer connected to the neutral wire of the network.

In FIG. 1 is a diagram of the inventive electromagnetic current compensator of the third harmonic in three-phase four-wire networks.

The third-harmonic electromagnetic current compensator in three-phase four-wire networks contains a three-phase half-wave rectifier 1, four current transformers 2-5, a filter 6 with a passband of 150 Hz, windings 7-9 and NC contacts 10-12 of three current relays and three circuits 13-15 of series-connected capacitor and resistor. Current transformer 2 is connected by its primary winding to the neutral wire N, and current transformers 3-5 are connected to the phase wires of the network L1, L2, L3, the beginning of the secondary winding of current transformer 2 and the beginning of the secondary windings of current transformers 3-5 form a common point. The ends of the secondary windings of current transformers 3-5 are connected to the anodes of a three-phase half-wave rectifier 1. The cathodes of a three-phase half-wave rectifier 1 are connected to common points and connected to the end of the secondary winding of current transformer 2 through a filter 6 with a passband of 150 Hz 2. Parallel to the secondary windings of current transformers 3- 5, windings 7–9 of three current relays and three circuits 13–15 from a series-connected capacitor and resistor are connected. Serially connected breaking contacts 10-12 of three current relays bypass the secondary winding of current transformer 2.

An electromagnetic current compensator of the third harmonic in three-phase four-wire networks operates as follows.

Single-phase nonlinear loads cause non-sinusoidal currents to flow in the phase and neutral wires of a four-wire network, among which the third harmonic dominates. From the flow of the main harmonic currents through the primary windings of current transformers 3-5, secondary currents are induced in the secondary windings of these current transformers. The diodes of a three-phase one-half-wave rectifier 1 are switched on alternately in 1/3 of the industrial frequency period. The current will be conducted by that diode of a three-phase half-wave rectifier 1, the anode potential of which relative to the common point of the secondary windings of current transformers 3-5 is higher than that of other diodes. The multiplicity of the ripples of the rectified current flowing in the secondary winding of the current transformer 2, in relation to the main frequency of the primary network is equal to three. To compensate for the DC component and unwanted harmonics of the rectified current, a filter 6 with a passband of 150 Hz is introduced. As a result, the current flowing through the current transformer 2 will contain only currents with a frequency of 150 Hz, and the secondary windings will not be additionally heated. The windings 7-9 of three current relays will receive power from current transformers 3-5 in those cases when the corresponding diode of a three-phase half-wave rectifier 1 will not conduct current, that is, alternately 2/3 of the industrial frequency period. Three circuits 13-15 of a series-connected capacitor and resistor slow down the action of three current relays and do not allow contacts 10-12 of three current relays to close, supplying windings 7-9 of three current relays in 1/3 of the industrial frequency period, when the corresponding three-phase diode a half-wave rectifier 1 conducts current. The setting of the three current relays is selected so that during the minimum load of the electric network exclude the possibility of overcompensation of the current of the third harmonic by shunting the secondary winding of the current transformer 2 using the breaking contacts 10-12 of three current relays.

Thus, the claimed third-harmonic electromagnetic current compensator in three-phase four-wire networks provides improved third-harmonic compensation accuracy by eliminating the overcompensation mode, which improves the quality of electric energy, reduces active power loss and voltage loss in all elements of a three-phase four-wire network from the third harmonic current.

Claims (1)

An electromagnetic compensator of the third harmonic current in three-phase four-wire networks, containing a three-phase one-half-wave rectifier, four current transformers, one of which is connected with its primary winding to the neutral wire, and the other three to the phase wires of the network, characterized in that a filter with a strip is additionally introduced into it 150 Hz transmitters, three current relays and three circuits from a series-connected capacitor and resistor, while the windings of three current relays are connected in parallel with the secondary windings of three transforms tori currents included in the phase wires of the network, and the serially connected disconnecting contacts of the three current relays bypass the secondary winding of the current transformer included in the neutral wire of the network, circuits from the series-connected capacitor and resistor are connected in parallel with the windings of the three current relays, while the start of the secondary windings of three current transformers included in the phase wires of the network are connected to a common point and connected to the beginning of the secondary winding of the current transformer included in the neutral wire And the ends of the three current transformers included in the phase conductors of the network are connected to the anodes of three-phase half-wave rectifier, the cathodes of which are connected to a common point and are connected through a filter with a bandwidth of 150 Hz to the end of the current transformer secondary winding included in the neutral wire network.

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