UA124582C2 - THREE-PHASE CURRENT HARMONIC FILTER - Google Patents

Abstract

The three-phase harmonic current filter belongs to electrical engineering, namely to electric power filters and can be used to improve the electrical compatibility of nonlinear loads with the mains. The three-phase harmonic current filter contains a magnetic core with non-magnetic gaps, which includes three rods, each of which has phase and resonant windings wound in series. Each rod corresponds to one of the three phases of the power supply system. Two yokes are located at the ends of these rods and close their magnetic fluxes. The phase winding for each phase is connected at one end to the input of the filter, and the other - to the beginning of the resonant winding, the end of which is connected to the first terminal of the first capacitor of the capacitor bank. The load is connected to the connection point of the phase and resonant windings. Additionally, a current relay, a contactor and a second capacitor for each phase are introduced, and the first terminal of the second capacitor is connected to the first terminal of the first capacitor, and the second terminal terminal is connected to the second terminal of the first capacitor, and the second terminal of the first capacitor and resonant windings of the next phase. The current relay is connected to the load input of one of the phases, and its closing contact is connected at one end to the phase of the voltage source, and the other end to the first terminal of the contactor, the second terminal of which is connected to the second phase of the voltage source. The technical result is to improve the filtering capabilities of the device and limit the voltage on the load in modes close to idling at a given level.

Description

The invention belongs to electrical filters and can be used as a filter of harmonic components generated by non-linear loads in electrical equipment of various purposes.

There is a well-known universal filter of harmonics produced by the company "MIKO5" (Canada), for example, Ipeaiig (1). It consists of a three-phase choke, which has three windings placed on each rod in each phase, and a group of capacitors, moreover, the first winding in each phase is connected by its beginning to the network, and its end is connected to the end of the second winding, and to the connection point the beginning of these windings includes the third winding, the end of which is connected to the capacitor, which, in turn, is connected to the capacitors of the other phases in a "delta" or "star", and a load is connected to the free beginning of the second winding.

The disadvantage of this filter is that all the windings are placed on a common magnetic circuit and there is a magnetic connection between them, as a result of which the harmonics flowing in the resonant third winding are transformed into other windings and further into the power supply network, thereby reducing the filtering efficiency . To improve it, it is necessary to increase the value of the inductance of the choke's input winding, which leads to an increase in the dimensions of the filter and the funds for its manufacture, and functionally to an increase in the voltage at the output of the filter in modes close to idling.

The closest technical solution is a filter with a magnetic shunt (2), chosen as a prototype, designed to suppress harmonics of currents generated by non-linear loads, which has an input connected to the power supply system and an output connected to the load and consisting of a magnetic a heart that has three rods. Each rod corresponds to one of the three phases of the power supply system, and also has at least one magnetic shunt that passes through all the rods and is magnetically connected in their middle part.

The first and second parts of the core on each of the two sides of the shunt have for each phase - a phase winding, which has one end for connection with the first phase and the second end, and this phase winding is located on the first part of the core; for each phase, a second (resonant) winding having a first end connected to the second end of the phase winding and a second end of the winding connected to the capacitor.

The capacitor has a second output connected to the second phase or to the second capacitor, which

Zo is connected to the second phase, and the phase and resonant windings are connected by means of a magnetic shunt, and the load is connected in each phase to the point of connection of the phase and resonant windings. The core has one or more non-magnetic gaps. Thanks to this design, the magnetic fluxes created by the phase and resonant windings are separated by means of a magnetic shunt, which greatly weakens the magnetic connection between the windings.

The main disadvantages of this filter are the complexity of manufacturing the filter core and the impossibility of reducing the voltage in modes close to idling to a given level. These disadvantages narrow the field of application of the filter and worsen its filtering properties.

The task of the invention is to create such a filter of current harmonics, in which, due to the reduction of the voltage in modes close to idling, to the required dimensions, and the ability to change the parameters of the resonant branch of the filter depending on the harmonic that prevails in the current consumed by the load, a new technical result is achieved: expansion of the filter's functional capabilities, improvement of the quality of the current consumed from the network, improvement of the filter's filtering capabilities, simplification of the filter core manufacturing technology.

The task is solved due to the fact that the three-phase current harmonic filter has a magnetic core with non-magnetic gaps, which includes three rods, on each of which there are phase and resonance windings wound in series, and each rod corresponds to one of the three phases of the power supply system, and two yokes placed at the ends of these rods, which close their magnetic fluxes, for each phase, the phase winding is connected with one end to the input, and the other to the beginning of the resonance winding, the end of which is connected to the first terminal of the first capacitor of the capacitor bank, the load is connected to the connection point of the phase and resonance windings, the second terminal of the first capacitor is connected to the connection point of the phase and resonance windings of the next phase, a current relay, a contactor and a second capacitor are additionally introduced, and the first terminal of the second capacitor is connected to the first terminal of the first capacitor, and the second output through the contactor contact - to the second output of the first k capacitor, the current relay is connected to the load input of one of the phases, and its closing contact is connected at one end to the phase of the voltage source, and at the other end - to the first terminal of the contactor, the second terminal of which is connected to the second phase (516) of the voltage source.

The technical result is achieved by the fact that the phase and resonant windings are placed as in a conventional three-phase choke on one magnetic core without a magnetic shunt, which greatly simplifies the design of the filter, and in order to limit the voltage in modes close to idle speed, a current relay, a commutator and a second capacitor, and the relay measures the load current and, depending on its value, turns on or off the switch, which in turn turns on or off the second capacitor in parallel with the first.

A comparative analysis of the claimed device with the prototype shows that the filter is distinguished by the presence of new connections, which consist in the appropriate connection of circuit elements with each other and with the elements of the prototype in the above manner and new elements, namely: current relay, contactor, the second group of capacitors of the capacitor bank. The new elements and connections of this filter are designed for their practical implementation with the achievement of a new technical result. The claimed device meets the "novelty" criterion.

On the basis of the above, it can be concluded that the set of essential distinguishing features reflected in the formula of the proposed invention is necessary and sufficient to achieve a new technical result, namely, the improvement of filtering properties and expansion of the filter's functionality. account of the appropriate combination of filter elements and changes in the capacity of the capacitor bank in accordance with urgent technical needs.

The essence of the invention is explained by the drawing. In Fig. the basic electrical diagram of the proposed filter is shown. It contains for each phase phase windings 1, 2, 3, which are connected at one end to the power source, and at the other end to the beginning of the resonance windings 4, 5, 6, the end of which is connected to the first terminals of the capacitors 7, 8, 9, the second outputs of which are connected to the connection point of the phase and resonance windings of the next phase.

The three-phase current harmonic filter is additionally provided with capacitors 10, 11, 12, which are connected with one terminal to the first terminals of capacitors 7, 8, 9, and with their second terminals to the closing contacts 13, 14, 15 of the contactor 16 connected to the phase of the power source.

The second terminals of contacts 13, 14, 15 are connected to the second terminals of capacitors 7, 8, 9. In addition, a current relay 17 is connected to the load input of one of the phases, the closing contact of which is 18

One end is connected to the phase of the power source, and the other to the coil of the contactor 16.

Loads 19, 20, 21 in each phase are connected to the connection point of the phase and resonance windings.

The three-phase current harmonic filter works as follows.

To limit the voltage level in modes close to idling, the load is started from the idling mode when the capacitors 7, 8, 9 are turned on, the capacity of which is selected taking into account the given voltage level at the load. When the load current reaches the set value, the current relay 17 is activated, which, through its contact 18, supplies voltage to the contactor 16, and the latter connects the capacitors 10, 11, 12 to the battery, and further operation of the filter occurs at the total capacity of both capacitors, which provides the required degree filtering in nominal modes. The value of the load at which the current relay is activated is selected so that when connecting capacitors 10, 11, 12, the voltage on the load exceeds the specified level. When the load is reduced to the release level of the current relay 17, the latter activates and disconnects the contactor 16 from the power supply network, and therefore the capacitors 10, 11, 12. Further reduction of the load occurs with capacitors 7, 8, 9, which provide the required voltage level on the load.

In addition, changing the connection scheme of the capacitor of the resonance branch of the filter significantly improves the filtering properties, which in turn allows reducing the size of the filter and its cost.

Therefore, the introduction of a filter, current relay, contactor into the circuit and the execution of a capacitor bank in the form of two parts, one of which can be connected (disconnected) depending on specific conditions, leads to a decrease in the voltage in modes close to idling to a given level. That is, the proposed three-phase harmonic filter has extended functionality.

As a result of the above, effective use of the proposed filter is assumed under the conditions of a limited voltage level on the load and the need to have the functional ability to adapt the filter parameters depending on the spectrum of harmonics generated by the load. The last advantage of the proposed filter is especially relevant in the case of its application to a group of nonlinear loads that have a different spectral composition,

therefore, connecting or disconnecting one of the loads leads to a sharp change in the spectrum of harmonics in the network.

The three-phase filter of current harmonics is made as a mock-up sample with a capacity of 5 kVA. Its experimental testing confirmed its operability and efficiency in comparison with known solutions, as well as the prospects for its further use.

The parameters and characteristics of the filter obtained as a result of the research correspond to a new technical solution in their entirety due to the new elements and connections set forth in the claims, namely: the expansion of the filter's functionality, which is accordingly solved as a result of the introduction of a current relay, a contactor and a capacitor bank, consisting of two parts, one of which can be connected (disconnected) depending on specific requirements, as well as thanks to the introduction of new connections, led to an improvement in the filtering capabilities of the filter.

Sources of information: 1. Hemip M., MoiKom I. Raiepi Opimegza! Nagtopis Miidaipo Zubiet / Fish. Me 5 6, 127, 743//10.01.2000. 2. Hemip M., Noemepaag:5 A., MoiYikom I. Raiepi arriisayop ribiisayop /Nagtopis tiiidaitpu aemise m/yp tadpeis zpypi /Ryr. MeO5 2006 /0197385 Ah! (O5A) //Zer.7.2006.

Claims (1)

DISCLOSURE OF THE INVENTION A three-phase current harmonic filter containing a magnetic core with non-magnetic gaps, which includes three rods, on each of which there are phase and resonance windings wound in series, and each rod corresponds to one of the three phases of the power supply system, and two yokes , placed at the ends of these rods, which close their magnetic fluxes, while the phase winding for each phase is connected with one end to the input of the filter, and with the other - to the beginning of the resonant winding, the end of which is connected to the first terminal of the first capacitor of the capacitor bank , and the load is connected to the connection point of the phase and resonance windings, which is characterized by the fact that a current relay, a contactor and a second capacitor are additionally introduced for each phase, and the first terminal of the second capacitor is connected 30 to the first terminal of the first capacitor, and the second terminal through the contact contactor is connected to the second output of the first capacitor, and the second output of the first capacitor is connected connected to the point of connection of the phase and resonance windings of the next phase, while the current relay is connected to the load input of one of the phases, and its closing contact is connected at one end to the phase of the voltage source, and at the other end - to the first output of the contactor, the second output 35 which is connected to the second phase of the voltage source. 3 iv t 3 ! Kan and Z i EE and same 8 t g ; nena p 4: shk kesh she Fig.