LLCL filter with LRC (Longitudinal Redundancy Check) parallel passive damping circuit

A passive damping and damping circuit technology, which is applied in the field of LLCL filters, can solve problems such as difficulties, lower system efficiency, excessive heat generation of series resistors, etc., and achieve the effects of reducing damping resistor losses, reducing inductance, and improving system efficiency.

Active Publication Date: 2014-12-10
HEFEI UNIV OF TECH
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  • Application Information

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Problems solved by technology

However, although the LLCL filter with this structure can also increase the system damping and ensure the stability of the system, it will significantly weaken the attenuation performance of the LLCL filter at a specific frequency, and the series resistance will flow through the large fundamental frequency and low frequency current, resulti

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  • LLCL filter with LRC (Longitudinal Redundancy Check) parallel passive damping circuit
  • LLCL filter with LRC (Longitudinal Redundancy Check) parallel passive damping circuit
  • LLCL filter with LRC (Longitudinal Redundancy Check) parallel passive damping circuit

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Embodiment Construction

[0019] The preferred mode of the present invention will be described in further detail below in conjunction with the accompanying drawings.

[0020] See figure 1 The composition of LLCL filter with LRC parallel passive damping circuit is as follows:

[0021] Bridge arm inductance L 1 And grid side inductance L 2 After being connected in series, the two ends are respectively the inverter 1 bridge arm side output terminal 2 and the grid 3 terminal 4; the bridge arm inductance L 1 And grid side inductance L 2 A parallel damping circuit 7 and a series resonant branch connected in series are connected across the contact 3 of the inverter 1 and the other common terminal 6 of the power grid 5, wherein the parallel damping circuit 7 consists of a damping resistor R connected in parallel. d , Damping inductance L d And damping capacitor C d The LC resonant frequency is the same as that of the LLCL filter, and the series resonant branch has an additional inductor L f And filter capacitor C f C...

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Abstract

The invention discloses an LLCL filter with an LRC (Longitudinal Redundancy Check) parallel passive damping circuit. A parallel damping circuit (7) is in tandem connection between a connection joint (3) of a bridge arm inductance (L1) and a grid-side inductance (L2) and a parallel resonance branch circuit; the parallel damping circuit (7) is formed by a damping resistor (Rd), a damped inductance (Ld) and a damping capacitor (Cd) which are in parallel connection; the LC resonance frequency of the parallel damping circuit is identical to that of the LLCL filter; two ends of the LLCL filter are provided with an inverter (1) bridge arm lateral output terminal (2) and a grid (3) terminal (4) after the bridge arm inductance (L1) and the grid-side inductance (L2) are in tandem connection; a series resonance branch circuit which is formed by an additional inductance (Lf) and a filter capacitor (Cf) is in bridge joint between the connection joint (3) and a common terminal (6) of the inverter (1) and the power grid (5). The LLCL filter with the LRC parallel passive damping circuit in a large-power grid-connected inverter can meanwhile satisfy the high-frequency filter effect, the damping loss and the system stability.

Description

Technical field [0001] The invention relates to a PWM inverter output filter, in particular to an LLCL filter with an LRC parallel passive damping circuit. Background technique [0002] In high-power grid-connected inverters, LCL filters have been widely used due to their small size, low cost, and high harmonic attenuation rate of high-frequency currents. However, when the switching frequency is low, in order to filter out the harmonics of the switching frequency and its integer multiples generated by the inverter to meet the harmonic requirements of the grid standard on the inverter output current, the cut-off frequency of the LCL filter needs to be more Low, which not only needs to increase the filter parameters, which increases the cost of the inverter, but also limits the bandwidth of the system control and reduces the dynamic performance and stability of the system. [0003] In order to solve this problem, people have made some efforts, such as a "filter with specific frequen...

Claims

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Application Information

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IPC IPC(8): H02M1/12H03H7/06
Inventor 张兴任康乐王付胜屠运武邓立荣汪令祥
Owner HEFEI UNIV OF TECH
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