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Precise phase locking method based on cross decoupling self-adaptive complex filter

A complex filter and self-adaptive technology, applied in the field of phase lock, can solve the problems of complex implementation and large phase lock error

Inactive Publication Date: 2010-03-17
YANSHAN UNIV
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  • Abstract
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  • Claims
  • Application Information

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Problems solved by technology

[0007] The purpose of the present invention is to solve the problems of large phase-locking errors and complex implementations in the above-mentioned prior art, and propose a precise phase-locking method based on cross-decoupling adaptive complex filters. Extract the positive sequence component of the grid voltage and its information under extremely harsh industrial site conditions such as unbalanced three-phase voltage and large-scale fluctuations in voltage and frequency, so that the grid-connected converter can achieve fast and accurate phase-locking under the above-mentioned harsh conditions

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  • Precise phase locking method based on cross decoupling self-adaptive complex filter

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Embodiment Construction

[0029] The specific implementation manners of the present invention will be described in further detail below in conjunction with the accompanying drawings.

[0030] The core idea of ​​the present invention is: firstly, the positive sequence component of the voltage is extracted by using a cross-decoupling adaptive complex filter, and then phase-locked separately.

[0031] Basic principle of the present invention is as follows:

[0032] Set the three-phase voltage input signal U a , U b , U c for:

[0033]

[0034] Among them, U m + , ω 0 with are positive sequence voltage amplitude, frequency and phase, respectively. u m - , ω 0 with are the negative sequence voltage amplitude, frequency and phase, respectively. u ha , U hb and U hc are the harmonic voltages, respectively.

[0035] For the convenience of analysis, the harmonic voltage in formula (1) is ignored first, and then after Clarke transformation, the voltage signal U in the αβ coordinate system c...

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Abstract

The invention relates to a precise phase locking method based on a cross decoupling self-adaptive complex filter, which comprises the following steps: firstly carrying out the Clarke coordinate transformation on three-phase voltage input signals of Ua, Ub and Uc for obtaining voltage signals of Ualpha and Ubeta under an alpha-beta coordinate system; then leading the voltage signals to pass throughthe cross decoupling self-adaptive complex filter for extracting positive sequence voltage components *alpha<plus> and *beta<plus> under the alpha-beta coordinate system; further carrying out the Clarke inverse transformation on the *alpha<plus> and the *beta<plus> for obtaining three-phase voltage positive sequence components of *a<plus>, *b<plus> and *c<plus> under an a-b-c coordinate system; carrying out the Park transformation on the *alpha<plus> and the *beta<plus> for obtaining a d-axis component *d<plus> and a q-axis component *q<plus> under a d-q coordinate system, wherein, the q-axiscomponent *q<plus> reflects the positive sequence amplitude; leading the d-axis component *d<plus> to pass through a PI regulator to obtaining the frequency estimated value *0; feeding the *0 back tothe cross decoupling self-adaptive complex filter for realizing the frequency self-adaption; and carrying out integration on the *0 for 1 / s for obtaining the positive sequence phase *<plus>. The precise phase locking method is characterized by simpleness, easy realization, high phase-locking precision and fast speed, thereby being particularly applicable to the precise phase locking of grid-connected converters under the extreme industrial field situations of power grid voltage distortion, three-phase voltage imbalance, large fluctuation range of voltage frequency and the like.

Description

technical field [0001] The invention belongs to a phase-locking method, in particular to an accurate phase-locking method based on a cross-decoupling adaptive complex filter. Background technique [0002] In the application field of grid-connected converters, grid voltage distortion, sag, unbalance and frequency fluctuations may occur in industrial power grids, which will affect the operation status of grid-connected converters. In order to achieve stable operation control of grid-connected converters, it is necessary Extract the positive sequence component of grid voltage and its amplitude and phase information. [0003] Traditional phase-locking methods mainly include: zero-crossing phase-locking method, synchronous rotating coordinate system phase-locking method, and positive and negative sequence rotating coordinate system phase-locking method. [0004] ① Zero-crossing phase-locking method: This method first establishes a phase reference table offline according to the g...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): H02J3/38
Inventor 邬伟扬郭小强王立乔
Owner YANSHAN UNIV
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