Lossless clamping network of primary side feedback flyback converter and design method

Abstract

The invention provides a novel lossless clamping network of a primary side feedback flyback converter and a design method. The novel lossless clamping network comprises capacitors C11 and C12, an inductor L, diodes D11 and D12, and a voltage stabilizing diode Dz, and is composed of three branches, namely a branch formed by connecting the capacitors C11 and C12 in parallel, a branch of the diode D11 and a branch formed by connecting the diode D12 and the inductor L in series. According to the invention, double capacitors with different capacities are connected in parallel, the large capacitor C12 effectively suppresses voltage overshoot and achieves the clamping function, and the small capacitor C11 improves the response speed; according to different properties of branches, the clamping network is composed of three branches: a capacitor C11 and a capacitor C12 are connected in parallel, so that the response speed is improved, and the voltage peak in the switching-off process of a switching tube is suppressed; the branch of the diode D11 is conducted in the switching-off process of the switching tube, so that a channel is provided for transferring leakage inductance energy to the clamping network; and the diode D12 and the inductor L are connected in series to form a branch, and the capacitor is fed back to store energy in an LC resonance mode in the switching-on process of the switching tube, so that partial drain current of the switching tube is formed.

Description

technical field [0001] The invention relates to an electronic field; in particular, it relates to a novel lossless clamping network and a design method of a primary-side feedback type flyback converter. Background technique [0002] Due to the advantages of simple structure, small size and low cost, the flyback converter has high application value in small and medium power applications, especially the primary side feedback flyback converter, because of its excellent isolation performance, it is more applicable to widely. However, due to the inevitable leakage inductance of the transformer that plays the role of isolation and energy storage in the converter, a huge voltage spike will be generated at the moment the switch tube is turned off, causing the switch tube to withstand high voltage stress, and may even cause the switch tube to be damaged. , affecting the stable operation of the converter; at the same time, the leakage inductance loss reduces the efficiency of the fly...

AI Technical Summary

Problems solved by technology

[0005] (1) The traditional active clamping network is effective in suppressing peak voltage, but each main circuit requires a set of independent active clamping circuits, especially when the main circuit is multi-channel interleaved and paralleled, which increases the difficulty and transformation of the driving circuit device cost

[0006] (2) The traditional RCD clamp consists of diodes, clamp resistors and clamp capacitors. The topology of the RCD clamp network is simplified and can suppress peak voltages. However, the leakage inductance energy absorbed by the clamp network is dissipated on the resistance heating, resulting in topological low efficiency

The clamp ...

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